Identification of genes whose expression patterns distinguish benign lymphoid tissue and mantle cell, follicular, and small lymphocytic lymphoma

ABSTRACT

Provided are genes whose expression patterns allow differentiation between benign lymph node tissue, follicular lymphoma tissue, mantle cell lymphoma tissue and small lymphocytic lymphoma tissue. These genes are useful as diagnostic markers for lymphoma. The protein products of these genes are useful in diagnostic and therapeutic applications, including monoclonal antibodies, lymphoma-specific chemotherapeutic agents, and gene therapies.

CROSS-REFERENCE TO RELATED APPLICATIONS

[0001] This application takes priority to U.S. provisional application Serial No. 60/337,862, filed Dec. 7, 2001 which is incorporated herein to the extent not inconsistent with the disclosure herewith.

BACKGROUND OF THE INVENTION

[0002] The identification of genes whose patterns of expression are cancer-specific will lead to better management of cancer patients. New tests fall into four areas: (a) tests designed to classify a patient's cancer (diagnosis), (b) tests designed to predict a patient's clinical course (prognosis), (c) tests designed to determine which subset of patients with a particular type of cancer will respond to particular drugs (pharmacogenomics), and (c) tests to monitor patient response to therapy (monitoring). Genes identified as over- or under-expressed in cancer also serve as important targets for the process of drug discovery and have utility as gene therapy agents.

[0003] DNA array technology (Schena, Shalon et al. 1995; Wodicka, Dong et al. 1997) provides the means to analyze the expression of hundreds to thousands of biomarkers in parallel. A DNA array is a device containing probes on a solid support that are designed to detect a large number of different DNA sequences. These devices allow quantification of the expression of thousands of distinct genes. Each gene generally encodes a single protein, which is the functional product of the gene. In the process of gene expression, each gene is copied into an intermediate form known as messenger RNA (mRNA). Genes that are expressed at high levels give rise to many copies of mRNA, whereas genes that are not expressed or expressed at low levels express few to no mRNA copies. DNA arrays facilitate the quantitative measurement of thousands of different mRNAs simultaneously.

[0004] The biological behavior of tissues, such as cancerous tissues, reflects the quantities and activities of the gene products that the tissue is expressing. Thus, by using DNA arrays to measure mRNAs as surrogates for measuring protein levels directly, one can obtain quantitative information about the biology of cells and tissues. For this reason, the use of DNA arrays containing probes directed against appropriate cancer-specific genes has been suggested as a way of augmenting current diagnostic methods (Brugarolas, Haynes et al. 2001). Currently available DNA arrays contain probes for thousands of human genes (a significant fraction of all human genes). This nearly comprehensive representation of the human genome on arrays has facilitated the search for genes whose patterns of expression are cancer-specific. Once cancer-specific genes are identified, dedicated customized DNA arrays can be designed to measure the expression of selected genes. Diagnostically useful genes may include genes whose up- or down-regulation is the result of oncogene mutation. Biomarker genes may correlate with the presence of specific chromosomal translocations. Finally, genes not previously known to be associated with a molecular determinant of cancer may serve as useful cancer-specific biomarker genes.

[0005] In the area of lymphoma biology, DNA array technology has been used to study novel lymphoma markers (Chan and Huang 2001) (Husson, Carideo et al. 2002) (Aalto, El-Rifa et al. 2001) (Stratowa, Loffler et al. 2001) (Hofmann, de Vos et al. 2001), to study distinct subtypes of diffuse large B-cell lymphoma (DLBCL) (Alizadeh, Eisen et al. 2000) (Shipp, Ross et al. 2002), to study molecular pathways potentially involved in lymphoma pathogenesis (Davis, Brown et al. 2001), and to predict the survival of DLBCL lymphoma patients after chemotherapy (Rosenwald, Wright et al. 2002).

[0006] There is particular need to discover cancer-specific genes expressed in hematologic cancers (leukemias and lymphomas) since this group of diseases is not optimally diagnosed or treated using current methods. Numerous classification schemes have been used in the diagnosis of hematologic cancers. The recently adopted World Health Organization (WHO) classification of hematopoietic neoplasms, which divides lymphomas into more than 40 distinct entities (Harris, Jaffe et al. 1999), underscores the diversity of these cancers. Indeed, within individual WHO diagnostic categories, cancers vary greatly in prognosis and in response to therapy due to inherent but poorly characterized biological heterogeneity (Cousar, Sawyers et al. 1999). It is likely that each WHO category encompasses multiple biologically distinct disease processes with different natural histories and responses to therapy. Currently, hematologic diagnoses are made using (a) gross and microscopic morphological examination, (b) detection of characteristic chromosomal rearrangements using nucleic acid hybridization, polymerase chain reaction (PCR), reverse transcription-PCR (RT-PCR), and cytogenetic analysis, and (c) detection of aberrant gene expression using PCR, RT-PCR, nucleic acid hybridization, and monoclonal antibodies. Due to the complexity of these diagnostic tests and subjectivity involved in test interpretation, obtaining accurate hematopathologic diagnoses is challenging for pathologists and clinicians. It may be relatively common, for example, that the same lymphoma would be categorized differently by different pathologists (listed 1997). Further, some cases of lymphoma lack features that allow them to fit neatly into any classification scheme.

[0007] Approximately 53,900 new cases of non-Hodgkin's lymphoma are diagnosed in the U.S. annually (Jemal, Thomas et al. 2002). Together, low-grade B cell lymphomas (LGBCLs), including follicular lymphoma (FL), mantle cell lymphoma (MCL), and chronic lymphocytic lymphoma/small lymphocytic lymphoma (CLL/SLL), comprise one-third of cases (Ries, Miller et al. 1994). LGBCLs are indolent but generally not curable (Voliotis and Diehl 2002). The time from diagnosis to death is quite variable, ranging from months to 20 years (Homing 2000). Advances in understanding the biological basis, clinical behavior, and treatment of LGBCL rely on accurate diagnoses. The currently used WHO lymphoma classification scheme is based on tumor morphology, molecular abnormalities, and the measurement of a limited number of immunocytochemical markers (Harris, Jaffe et al. 1999). It is likely that current LGBCL diagnostic categories encompass multiple molecularly distinct subtypes of disease with different clinical features and responses to therapy. Tools that allow the measurement of a larger number of relevant markers will lead to improvements in diagnostic classification.

[0008] FL is characterized histologically by the replacement of normal lymph node architecture with nodular collections of small cleaved and large non-cleaved neoplastic B cells. By flow cytometry, FL cells are typically CD5−, CD10+/−, CD23+/−, and CD43− (Elenitoba-Johnson and Kjeldsberg 2000). The clinical course of patients with FL is highly variable. Survival depends on the histological type and other unknown factors (Homing 2000) (Seng and Peterson 1997). In approximately 30-40% of patients, low-grade FL undergoes transformation to clinically aggressive diffuse large B-cell lymphoma (DLBCL) and survival after transformation is often less than one year (Knutsen 1997). The t(14;18) chromosomal translocation is seen in 80-90% of FL cases (Dalla-Favera and Gaidano 2001). This translocation joins the BCL-2 gene with immunoglobulin (Ig) heavy chain locus, resulting in over-expression of the anti-apoptotic BCL-2 protein and extended cell survival (Hockenbery, Nunez et al. 1990) (Vaux, Cory et al. 1988). However, BCL-2 overexpression is necessary but not sufficient to cause FL (Limpens, de Jong et al. 1991) (Limpens, Stad et al. 1995) (Liu, Hernandez et al. 1994) (Strasser, Harris et al. 1993). Accordingly, few cases of FL exhibit t(14; 18) as the only clonal chromosomal abnormality (Knutsen 1997). Clinical heterogeneity of FL may reflect the variety of molecular abnormalities that synergize with BCL-2 over-expression (Dalla-Favera and Gaidano 2001).

[0009] MCL is characterized histologically by the accumulation of neoplastic cells that either diffusely efface lymph nodes or form expanded nodules surrounding germinal centers. MCL cells are typically CD5+, CD10−/+, CD23−, CD43+, and cyclin D1+. The expression of CD5 and the absence of CD23 expression are useful in distinguishing this tumor from FL (which is CD5−) and CLL/SLL (which is CD23+) (Elenitoba-Johnson and Kjeldsberg 2000). MCL carries a median survival of 3-4 years. However, there is considerable variability in survival time, ranging from 1 to 185 months (Norton, Matthews et al. 1995). The hallmark genetic lesion in MCL is the t(11;14) translocation that brings the CCND1 gene under control of the Ig heavy chain (IgH) locus, resulting in over-expression of cyclin D1. Cyclin D1 mediates progression through the cell cycle (Adams, Harris et al. 1999). As with t(14;18) in FL, the t(11;14) chromosomal translocation is apparently not sufficient to cause MCL (Bodrug, Warner et al. 1994) (Lovec, Grzeschiczek et al. 1994). Differences in clinical outcome may result from a variety of molecular defects that synergize with cyclin D1 overexpression to cause MCL.

[0010] CLL/SLL is a neoplasm of small round B lymphocytes found in the peripheral blood and lymph nodes. The most common immunophenotype is CD5+, CD10−, CD23+, and CD43+. The expression of CD23 and CD43 is useful in distinguishing this tumor from MCL (which is CD23−) and FL (which is CD43−) (Elenitoba-Johnson and Kjeldsberg 2000). The clinical course of patients with CLL/SLL is highly variable. In some patients, the disease does not alter life expectancy, whereas in others survival is less than 5 years (E Montserrat F Bosch J Internal Med 242 (Supp 74): 63) (Montserrat, Bosch et al. 1997). In 5% of CLL/SLL cases, neoplastic cells undergo transformation to DLBCL (known as Richter's syndrome), leading to rapid clinical deterioration (Montserrat, Bosch et al. 1997). It appears that the diagnostic category of CLL/SLL encompasses at least two distinct disease subtypes: (a) relatively good prognosis neoplasms arising from B-cells that have transited through the lymph node germinal center (GC) as evidenced by hypermutated Ig variable region genes, and (b) relatively poor prognosis neoplasms arising from pre-GC B-cells that lack hypermutated Ig variable region genes (Naylor and Capra 1999) (Hamblin, Davis et al. 1999). The molecular events leading to the development of CLL/SLL and the basis of clinical heterogeneity among CLL/SLL cases remain elusive (Capello and Gaidano 2000).

[0011] Molecular and clinical variability within current LGBCL classifications reflects the complex pathogenesis of cancer. The concerted effects of multiple gene products, which may have partially overlapping functions, regulate the proliferation, maintenance, senescence, and elimination of cells. Closely related cancers may contain various constellations of accumulated genetic defects resulting in different biological behavior (Klein 1993).

[0012] There is a need in the art for an improved classification scheme for LGBCLs and methods to differentiate between types of LGBCLs.

SUMMARY OF THE INVENTION

[0013] This invention provides a library of genes that allow differentiation between benign reactive lymph node tissue (RN), follicular lymphoma (FL), mantle cell lymphoma (MCL) and chronic lymphocytic lymphoma/small lymphocytic lymphoma (CLL/SLL). This invention also provides arrays using this set of genes, methods for making such arrays, and methods of using such arrays. The arrays of this invention are useful for determining gene expression profiles. Gene expression profiles are useful for determining expression profiles diagnostic of physiological conditions; diagnosing physiological conditions; identifying biochemical pathways, genes, and mutations involved in physiological conditions; identifying therapeutic agents useful for preventing and/or treating such physiological conditions; evaluating and/or monitoring the efficacy of such therapies, and creating and identifying animal models of human physiologic conditions. Arrays containing probes for all genes known to be useful in differentiating between benign reactive lymph node tissue (RN), follicular lymphoma (FL), mantle cell lymphoma (MCL) and chronic lymphocytic lymphoma/small lymphocytic lymphoma (CLL/SLL) are provided, as well as arrays containing subsets of such probes.

[0014] Also provided is an array comprising at least two isolated nucleotide molecules, each molecule having a sequence capable of uniquely hybridizing to a nucleic acid molecule having a sequence with at least 70% homology to a sequence listed in Table 2. Also provided is an array comprising at least two isolated nucleotide molecules, each molecule having a sequence capable of uniquely hybridizing to a nucleic acid molecule having a sequence with at least 80% homology to a sequence listed in Table 2. Also provided is an array comprising at least two isolated nucleotide molecules, each molecule having a sequence capable of uniquely hybridizing to a nucleic acid molecule having a sequence with at least 90% homology to a sequence listed in Table 2. Also provided is an array comprising at least two nucleic acid molecules or spots, each spot comprising a plurality of isolated nucleic acid molecules, each molecule having a sequence consisting essentially of a sequence listed in Table 2. Also provided is an array comprising at least ten nucleic acid molecules or spots, each spot comprising a plurality of isolated nucleic acid molecules, each molecule having a sequence consisting essentially of a sequence listed in Table 2. Also provided is an array comprising at least twenty nucleic acid molecules or spots, each spot comprising a plurality of isolated nucleic acid molecules, each molecule having a sequence consisting essentially of a sequence listed in Table 2. Also provided is an array comprising at least fifty nucleic acid molecules or spots, each spot comprising a plurality of isolated nucleic acid molecules, each molecule having a sequence consisting essentially of a sequence listed in Table 2. Also provided is an array comprising 120 nucleic acid molecules or spots, each spot comprising a plurality of isolated nucleic acid molecules, each molecule having a sequence consisting essentially of a sequence listed in Table 2.

[0015] Also provided is a method of selecting marker genes that distinguish between benign lymph node tissue, follicular lymphoma tissue, mantle cell lymphoma tissue and small lymphocytic lymphoma tissue comprising: preparing an array of probe genes; hybridizing labeled benign lymph node tissue, follicular lymphoma tissue, mantle cell lymphoma tissue and small lymphocytic lymphoma tissue with the array; analyzing the expression of the probe genes; selecting the marker genes that are differentially expressed by benign lymph node tissue, follicular lymphoma tissue, mantle cell lymphoma tissue and small lymphocytic lymphoma tissue.

[0016] Also provided is a method of determining an expression profile of a sample containing nucleic acid, comprising: providing the sample; providing an array of the invention; contacting said array with said sample under conditions allowing selective hybridization; and measuring hybridization of nucleic acid in said sample to said array to produce an expression profile. Two expression profiles may be generated and compared, for example, the expression profile of a sample known to correspond to a specific physiological condition may be compared with the expression profile of a sample taken from an organism to determine if the organism has the specific physiological condition.

[0017] The utility of this set of genes includes both diagnostic applications as well as the development of improved therapeutics. This gene set, or portions thereof, is used in a diagnostic DNA microarray that can diagnose various types of lymphoma. In this diagnostic DNA microarray, oligonucleotide probes for the lymphoma gene set are preferably used in a microarray format, where RNA extracted from patient tissue samples is labeled (preferably fluorescently, but other labels may be used, as known in the art) and applied to this microarray. Other testing methods such as kits containing the selected genes may be used, as known in the art. The amount of information gained from using a microarray for lymphoma diagnosis far exceeds that which can currently be gained from immunohistochemistry or flow cytometry, and the cost is reduced as well.

[0018] The protein targets of these genes can be used to generate monoclonal antibodies, as known in the art. These antibodies are useful to detect circulating lymphoma proteins for disease monitoring. The genes are also useful as targets for the development of lymphoma-specific pharmaceuticals. Drugs can be designed in a rational fashion to affect lymphoma cells without affecting normal tissues in a deleterious way, as known in the art. Finally, these genes can be used to combat lymphoma with gene therapy/gene transfer techniques. The expression of genes required for lymphoma cell proliferation can be specifically inhibited, and genes that interfere with the proliferation of lymphoma cells can be activated, as known in the art.

BRIEF DESCRIPTION OF THE DRAWINGS

[0019] The patent or application file contains at least one drawing executed in color. Copies of this patent or patent application publication with color drawing(s) will be provided by the Office upon request and payment of the necessary fee. FIG. 1 shows 48 genes differentially expressed among multiple tissue types. PolyA(+) RNA was pooled from 17 RN, 21 FL, 9 MCL, and 25 SLL specimens, respectively. Fluorescently labeled cDNA was generated from RNA and hybridized to microarrays containing cDNA probes for 14,976 IMAGE clones. Genes were selected based on ≧4-fold differential expression (p≦0.05 based on t-test analysis) between tissue types. Fold differential expression between the tissue types indicated in the figure legend is shown on the x-axis. Gene names and summary functions are shown to the left of y-axes.

[0020]FIG. 2 shows 72 genes differentially expressed only among two tissue types. PolyA(+) RNA was pooled from RN, FL, MCL, and SLL specimens. Fluorescently labeled cDNA was generated from RNA and hybridized to spotted cDNA microarrays. Genes were selected based on ≧4-fold differential expression (p≦0.05 based on t-test analysis) between tissue types. The x-axis shows fold differential expression between the tissue types indicated in the figure legends to the right of each graph. Gene names and summary functions are shown to the left of y-axes.

[0021]FIG. 3 is a summary flow chart depicting the comparison between gene expression data from microarray and qRT-PCR analyses. The expression of 39 of 120 genes identified by microarray analysis to be ≧4-fold differentially expressed was quantified by qRT-PCR. Using a threshold of ≧2-fold differential expression by qRT-PCR analysis, the expression patterns of 23 of the 39 genes were confirmed to be similar both by microarray and qRT-PCR methods.

[0022]FIG. 4 shows a graphical depiction of expression data for 23 genes whose gene expression profiles were similar by microarray and qRT-PCR analysis. The expression measurements for each gene in RN, FL, MCL, and SLL tissues were normalized to the expression level in a reference (tonsil) RNA sample. Each gene (identified at right) is represented by a single row of colored boxes; each tissue type is represented by a single column. Intensity of red indicates the degree of over-expression whereas intensity of blue indicates the degree of under-expression.

[0023]FIG. 5 shows that individual specimens of RN, FL, MCL, and SLL vary markedly in gene expression. The expression of (A) cyclin D1, (B) 13cDNA73, and (C) KIAA1407 in tonsil, 10 RN, 9 FL, 9 MCL, and 10 SLL individual specimens was quantified using qRT-PCR. Expression data for each gene was normalized to the level of cyclophilin expression. Tissue specimens are identified on the x-axes; relative expression is indicated on the y-axis. Two independent experiments were performed in duplicate. The results are presented as mean values (solid and gray bars for experiments 1 and 2) and SDs (error bars).

DETAILED DESCRIPTION OF THE INVENTION

[0024] New biomarkers that are useful in distinguishing currently-defined types of LGBCL and currently unrecognized subtypes of FL, MCL and SLL have been discovered. DNA arrays have been used to identify 120 genes whose patterns of expression distinguish among FL, MCL, SLL, and benign lymph node tissue. Two of these genes, 13cDNA73 and KIAA1407, show distinct expression among individual FL, MCL, and SLL specimens.

[0025] Gene expression has been extensively studied. Although the regulation of mRNA abundance by-changes in transcription or RNA degradation is by no means the only mechanism that regulates protein levels in a cell, virtually all differences in cell type or state can be correlated to changes in the mRNA abundance of several genes (Alizadeh, Eisen et al. 2000) (DeRisi. Iyer et al. 1997) (Schena, Shalon et al. 1995) (Schena Shalon et al. 1996).

[0026] DNA microarray analysis has been used to study diffuse large B-cell lymphoma (DLBCL) where microarrays were used to expand the diagnosis of DLBCL (Alizadeh, Eisen et al. 2000). While standard histological and morphological techniques had defined subsets of DLBCL, array analysis revealed two clinically distinct classes. These two newly discovered classes were indistinguishable by standard pathology, but expression analysis showed a differential expression of hundreds of genes. Correlation of these molecular differences with differences in the progression of the disease and clinical outcome has revealed that these two classes of DLBCL could be considered separate diseases (Alizadeh, Eisen et al. 2000).

[0027] Nucleic acid arrays have been described, e.g., in U.S. Pat. No. 5,837,832, U.S. Pat. No. 5,807,522, U.S. Pat. No. 6,007,987, U.S. Pat. No. 6,110,426, WO 99/05324, 99/05591, WO 00/58516, WO 95/11995, WO 95/35505A1, WO 99/42813, JP10503841T2, GR3030430T3, ES2134481T3, EP804731B1, DE69509925C0, CA2192095AA, AU2862995A1, AU709276B2, AT180570, EP 1066506, and AU 2780499. Such arrays can be incorporated into computerized methods for analyzing hybridization results when the arrays are contacted with prepared sample nucleotides, e.g., as described in PCT Publication WO 99/05574, and U.S. Pat. Nos. 5,754,524; 6228,575; 5,593,839; and 5,856,101. Methods for screening for disease markers are also known to the art, e.g., as described in U.S. Pat. Nos. 6,228,586; 6,160,104; 6,083,698; 6,268,398; 6,228,578; and 6,265,174.

[0028] Currently, DNA microarrays are the most efficient method to monitor correlative changes in gene expression and to investigate complex traits on a molecular level. Expression profiles assembled from multiple interrelated experiments are used to determine hierarchical connections between gene expression patterns underlying complex biological traits. These patterns are used to further define the molecular basis of complex disorders.

[0029] As used herein “array” refers to an ordered set of isolated nucleic acid molecules or spots consisting of pluralities of substantially identical isolated nucleic acid molecules. Preferably the molecules are attached to a substrate. The spots or molecules are ordered so that the location of each (on the substrate) is known and the identity of each is known. Arrays on a micro scale can be called microarrays. Microarrays on solid substrates, such as glass or other ceramic slides, can be called gene chips or chips.

[0030] As used herein, an “isolated nucleic acid” is a nucleic acid outside of the context in which it is found in nature. An isolated nucleic acid is a nucleic acid the structure of which is not identical to that of any naturally occurring nucleic acid molecule. The term covers, for example: (a) a DNA which has the sequence of part of a naturally-occurring genomic DNA molecule but is not flanked by both of the coding or noncoding sequences that flank that part of the molecule in the genome of the organism in which it naturally occurs; (b) a nucleic acid incorporated into a vector or into the genomic DNA of a prokaryote or eukaryote in a manner such that the resulting molecule is not identical to any naturally-occurring vector or genomic DNA; (c) a separate molecule such as a cDNA, a genomic fragment, a fragment produced by polymerase chain reaction (PCR), or a restriction fragment; and (d) a recombinant nucleotide sequence that is part of a hybrid gene, i.e., a gene encoding a fusion protein, or a modified gene having a sequence not found in nature.

[0031] As used herein “probe” refers to an isolated nucleic acid that is suitable for hybridizing to other nucleic acids when placed on a solid substrate. Probes for arrays can be as short as 20-30 nucleotides and up to as long as several thousand nucleotides. Probes can be single-stranded or double stranded. A probe usually comprises at least a partially known sequence that is used to investigate or interrogate the presence, absence, and/or amount of a complementing sequence. On the arrays of this invention, a probe is of such a sequence and the hybridization conditions of such stringency that each probe hybridizes substantially to only one type of nucleic acid per target sample.

[0032] As used herein, “target” or “target sample” refers to the collection of nucleic acids, e.g., reverse transcribed and labeled cDNA used as a prepared sample for array analysis. The target is interrogated by the probes of the array. A “target” or “target sample” may be a mixture of several prepared samples that are combined. For example, an experimental target sample may be combined with a differently labeled control sample and hybridized to an array, the combined samples being referred to as the “target” interrogated by the probes of the array. As used herein, “interrogated” means tested. Probes, targets, and hybridization conditions are chosen such that the probes are capable of interrogating the target, i.e., of hybridizing to complementary sequences in the target sample.

[0033] As used herein “printing” refers to the process of applying probes to a solid substrate, e.g., or applying arrays of probes to a solid substrate to make a gene chip. As used herein “glass slide” refers to a small piece of glass of the same dimensions as a standard microscope slide. As used herein, “prepared substrate” refers to a substrate that is prepared with a substance capable of serving as an attachment medium for attaching the probes to the substrate, such as poly Lysine.

[0034] As used herein “selective hybridization” refers to hybridization at moderate to high stringency such that only sequences of an appropriate homology can remain bound. Selective hybridization is hybridization performed at stringency conditions such that probes only hybridize to target sample nucleic acids that they are intended to hybridize with. Depending on the sequences of the probes and the target, the hybridization conditions are chosen to be appropriately selective. For example, if human sequences are used as probes for interrogating a human sample, selective hybridization could be at high stringency because, allowing for neutral polymorphism in humans, the sequences would be about 99-100% identical. When applying a chimpanzee target prepared sample to an array containing human sequence probes, selective hybridization would be at a lower stringency. Since hybridizing a target to an array is performed at one chosen hybridization stringency, probes are chosen so that they can undergo selective hybridization with the appropriate target molecules at the same hybridization stringency. As used herein “homology” refers to nucleotide sequence identity to a sequence, a molecule, or its complement.

[0035] As used herein, “clone” refers to an isolated nucleic acid molecule that may be stored in an organism such as E. coli. A clone is usually made of a vector and an insert. The insert usually contains a sequence of interest.

[0036] As used herein “physiological condition” refers to a healthy or unhealthy physiological state. As used herein “optimize an array for diagnosis” refers to selecting probes for an array such that only probes from genes necessary for diagnosis of one or more physiological conditions are included.

[0037] The microarrays or gene chips of this invention comprise probes placed in known positions on a solid substrate. A useful solid substrate is a specialized glass microscope slide. The arrays of this invention include arrays containing probes that detect some or all expressed sequences involved in mitochondrial biology in a selected species.

[0038] Arrays of this invention may contain control probes as well as probes for genes. Controls that can be included on the arrays of this invention include hybridization controls and scanning controls. The controls can be positive or negative controls. One type of hybridization control is spotting the same probe for a gene several times on one chip, each spot having different amounts of probe. This allows for the amount of probe of a given sequence to be optimized. Spotting too little probe may lead to a maximum hybridization signal resulting in a loss of data. Dimethyl sulfoxide (DMSO) can be used as a negative hybridization and scanning control. A spot of DMSO should give no signal. If there is any signal at a DMSO spot, the problem could be at hybridization or scanning steps. Plant sequences having sufficiently low homology with human and mouse sequences can also be utilized as negative hybridization and scanning controls. Plant sequences should not give any signal. A signal at a plant spot could indicate a problem with hybridization, i.e. too low a hybridization stringency was used, or with scanning, i.e., the chip was inserted into the scanner at the incorrect orientation. Poly A can be used as a positive hybridization specificity/non specificity control. A poly A spot should always give intense hybridization. No signal at a poly A spot could be the result of use of too high a hybridization stringency. Cy3 or Cy5 incorporated into a PCR product can be a positive scanning control. A spot on an array of a PCR product, or any other nucleic acid, that includes fluorescent label, should always give a signal, and if this sequence has no homology with any other sequence in the target, there should only be a signal of the label included in the nucleic acid. Control probes and probes for genes involved in mitochondrial biology can be duplicated, triplicated, etc. on the chip as printing controls. Controls for arrays can be purchased from Stratagene (SpotReport™, La Jolla, Calif., USA).

[0039] Standard targets and reference targets are also useful with the arrays of this invention, as is known in the art. When a prepared sample target to be interrogated is applied to an array of this invention, the results of the test are measured, i.e. by scanning, and recorded. These results can be compared directly to other test results using a similar array. However, it is much more accurate to include a differently labeled standard target in the hybridization mix with the prepared sample target. The results of the experimental sample target are then standardized, so that they can be compared accurately to the results of hybridizations of other sample targets. If ten different prepared sample targets are hybridized to arrays of this invention, simultaneously with the same prepared standard target, then the results of the ten sample targets can be accurately compared to each other. A prepared reference or control target for comparison can also be particularly pertinent to the experiment being performed. A prepared reference target could be a target sample derived from the same cell type from an animal of the same sex, age, and nuclear background as the experimental target sample, except for one difference, such as a different phenotype or treatment. Comparing the results of the experimental target with the results of an appropriate reference target yields a profile associated with the one difference being tested. When the hybridization results of a first sample are compared to the hybridization results of a second sample, the comparison can occur while the hybridization results of the first sample are being measured and recorded, or afterwards, by comparing the measured and recorded hybridization results of the two samples.

[0040] Probes on an array may be as short as about 20-30 nucleotides long or as long as the entire gene or clone from which they are derived, which may be up to several kilobases. A probe sequence may be identical (have 100% homology) to the portion of the gene it hybridizes to or it may be a mutated sequence. Mutated probes have less than 100% homology, such as about 98% homology, about 95% homology, about 90% homology, about 80% homology, or about 75% homology, or less, with the portions of the genes to which they hybridize. Arrays are designed such that all probes on an array can hybridize to their corresponding genes at about the same hybridization stringency. Probes for arrays should be unique at the hybridization stringencies used. Statistically, to be unique in the total human genome, probes should be at least about fifteen nucleotides long. A unique probe is only able to hybridize with one type of nucleic acid per target. A probe is not unique if at the hybridization stringency used, it hybridizes with nucleic acids derived from two different genes, i.e. related genes. The homology of the sequence of the probe to the gene and the hybridization stringency used help determine whether a probe is unique when testing a selected sample. Probes also may not hybridize with different nucleic acids derived from the same gene, i.e., splice variants. The location in the gene of the sequence used for the probe also helps determines whether a probe is unique when testing a selected sample. If the splice variants of a gene are known, ideally several different probes sequences are chosen from that gene for an array, such that each probe can only hybridize to nucleic acid derived from one of the splice variants. Arrays of this invention are used at hybridization conditions allowing for selective hybridization. At conditions of selective hybridization, probes hybridize with nucleic acid from only one gene. When an array is simultaneously hybridized with two targets or two prepared samples, each probe may hybridize with a nucleic acid in each prepared sample or target. When these two nucleic acids are from the same unigene cluster, the probe is said to hybridize with one gene, despite the fact that these nucleic acids may contain different labels.

[0041] The arrays of this invention can be utilized to determine profiles for related species by modifying the hybridization stringency appropriately. Sequence homology between organisms is known in the art. For example, human and chimpanzee sequences are about 98% identical. Consequently, human arrays are useful for profiling chimpanzees, with an appropriate lowering of the hybridization stringency. Hybridization stringency can be lowered by modifying hybridization components such as salt concentrations and hybridization and/or wash temperatures, as is known in the art.

[0042] The sequences useful for the arrays of this invention are useful for designing arrays for other species as well. To create an array for a new organism, the known sequences from the new organism, including expressed sequence tags (ESTs), are compared, by methods known to the art, with the sequences known to already be useful for other arrays. Sequence comparisons may be performed at the nucleic acid or polypeptide level. Homologous and analogous sequences from the new organism are thereby identified and selected for the new organism's mitochondrial array. The probes on the arrays of this invention are also useful as probes for identifying candidates for the new organism's array using molecular biology techniques that are standard in the art such as screening libraries.

[0043] All sequences given herein are meant to encompass the complementary strand, as well as double-stranded polynucleotides comprising the given sequence.

[0044] Microarrays of this invention can contain as few as two probes to as many as all the probes diagnostic of the selected physiological condition to be tested. Microarrays of this invention may also contain probes for all genes. The arrays of this invention may contain probes for at least about five genes, at least about ten genes, at least about twenty-five genes, at least about fifty genes, or all genes useful in differentiating between the conditions described herein. Arrays of this invention may comprise more than about five spots, more than about ten spots, more than about twenty-five spots, or all spots useful in differentiating between the conditions described herein.

[0045] Using microarrays may require amplification of target sequences (generation of multiple copies of the same sequence) of sequences of interest, such as by PCR or reverse transcription. As the nucleic acid is copied, it is tagged with a fluorescent label that emits light like a light bulb. The labeled nucleic acid is introduced to the microarray and allowed to react for a period of time. This nucleic acid sticks to, or hybridizes, with the probes on the array when the probe is sufficiently complementary to the labeled, amplified, sample nucleic acid. The extra nucleic acid is washed off of the array, leaving behind only the nucleic acid that has bound to the probes. By obtaining an image of the array with a fluorescent scanner and using software to analyze the hybridized array image, it can be determined if, and to what extent, genes are switched on and off, or whether or not sequences are present, by comparing fluorescent intensities at specific locations on the array. The intensity of the signal indicates to what extent a sequence is present. In expression arrays, high fluorescent signals indicate that many copies of a gene are present in a sample, and lower fluorescent signal shows a gene is less active. By selecting appropriate hybridization conditions and probes, this technique is useful for detecting single nucleotide polymorphisms (SNPs) and for sequencing. Methods of designing and using microarrays are continuously being improved (Relogio, Schwager et al. 2002) (Iwasaki, Ezura et al. 2002) (Lindroos, Sigurdsson et al. 2002).

[0046] Arrays of this invention may be made by any array synthesis methods known in the art such as spotting technology or solid phase synthesis. Preferably the arrays of this invention are synthesized by solid phase synthesis using a combination of photolithography and combinatorial chemistry. Some of the key elements of probe selection and array design are common to the production of all arrays. Strategies to optimize probe hybridization, for example, are invariably included in the process of probe selection. Hybridization under particular pH, salt, and temperature conditions can be optimized by taking into account melting temperatures and by using empirical rules that correlate with desired hybridization behaviors. Computer models may be used for predicting the intensity and concentration-dependence of probe hybridization.

[0047] Arrays, also called DNA microarrays or DNA chips, are fabricated by high-speed robotics, generally on glass but sometimes on nylon substrates, for which probes (Phimister 1999) with known identity are used to determine complementary binding. An experiment with a single DNA chip can provide researchers information on thousands of genes simultaneously. There are several steps in the design and implementation of a DNA array experiment. Many strategies have been investigated at each of these steps: 1) DNA types; 2) Chip fabrication; 3) Sample preparation; 4) Assay; 5) Readout; and 6) Software (informatics).

[0048] There are two major application forms for the array technology: 1) Determination of expression level (abundance) of genes; and 2) Identification of sequence (gene/gene mutation). There appear to be two variants of the array technology, in terms of intellectual property, of arrayed DNA sequence with known identity: Format I consists of probe cDNA (500˜5,000 bases long) immobilized to a solid surface such as glass using robot spotting and exposed to a set of targets either separately or in a mixture. This method, “traditionally” called DNA microarray, is widely considered as having been developed at Stanford University (Ekins and Chu 1999). Format II consists of an array of oligonucleotide (20˜80-mer oligos) or peptide nucleic acid (PNA) probes synthesized either in situ (on-chip) or by conventional synthesis followed by on-chip immobilization. The array is exposed to labeled sample DNA, hybridized, and the identity/abundance of complementary sequences is determined. This method, “historically” called DNA chips, was developed at Affymetrix, Inc., which sells its photolithographically fabricated products under the GeneChip® trademark. Many companies are manufacturing oligonucleotide-based chips using alternative in-situ synthesis or depositioning technologies.

[0049] Probes on arrays can be hybridized with fluorescently-labeled target polynucleotides and the hybridized array can be scanned by means of scanning fluorescence microscopy. The fluorescence patterns are then analyzed by an algorithm that determines the extent of mismatch content, identifies polymorphisms, and provides some general sequencing information (Chee, Yang et al. 1996). Selectivity is afforded in this system by low stringency washes to rinse away non-selectively adsorbed materials. Subsequent analysis of relative binding signals from array elements determines where base-pair mismatches may exist. This method then relies on conventional chemical methods to maximize stringency, and automated pattern recognition processing is used to discriminate between fully complementary and partially complementary binding.

[0050] Devices such as standard nucleic acid microarrays or gene chips, require data processing algorithms and the use of sample redundancy (i.e., many of the same types of array elements for statistically significant data interpretation and avoidance of anomalies) to provide semi-quantitative analysis of polymorphisms or levels of mismatch between the target sequence and sequences immobilized on the device surface. Such algorithms and software useful for statistical analysis are known to the art.

[0051] Using microarrays first requires amplification (generation of multiple copies of the same gene) of genes of interest, such as by reverse transcription. As the nucleic acid is copied, it is tagged with a fluorescent label that emits light like a light bulb. The labeled nucleic acid is introduced to the microarray and allowed to react for a period of time. This nucleic acid sticks to, or hybridizes, with the probes on the array when the probe is sufficiently complementary to the nucleic acid in the prepared sample. The extra nucleic acid is washed off of the array, leaving behind only the nucleic acid that has bound to the probes. By obtaining an image of the array with a fluorescent scanner and using software to analyze the hybridized array image, it can be determined if and to what extent genes are switched on and off, or whether or not sequences are present, by comparing fluorescent intensities at specific locations on the array. High fluorescent signals indicate that many copies of a gene are present in a prepared sample, and lower fluorescent signal shows a gene is less active. Expression levels for various genes under different conditions can be directly compared, such as for a cancer cell and a normal cell. Similarly, it can be determined what genes are turned on and off in response to certain stimuli such as a drug. Such information is valuable because it identifies genes in disease pathways and also is predictive of either efficacy or toxicity of drugs.

[0052] Probes fixed on solid substrates and targets (nucleotide sequences in the sample) are combined in a hybridization buffer solution and held at an appropriate temperature until annealing occurs. Thereafter, the substrate is washed free of extraneous materials, leaving the nucleic acids on the target bound to the fixed probe molecules allowing for detection and quantitation by methods known in the art such as by autoradiograph, liquid scintillation counting, and/or fluorescence. As improvements are made in hybridization and detection techniques, they can be readily applied by one of ordinary skill in the art. As is well known in the art, if the probe molecules and target molecules hybridize by forming a strong non-covalent bond between the two molecules, it can be reasonably assumed that the probe and target nucleic acid are essentially identical, or almost completely complementary if the annealing and washing steps are carried out under conditions of high stringency. The detectable label provides a means for determining whether hybridization has occurred.

[0053] When using oligonucleotides or polynucleotides as hybridization probes, the probes may be labeled. In arrays of this invention, the target may instead be labeled by means known to the art. Target may be labeled with radioactive or non-radioactive labels. Targets preferably contain fluorescent labels.

[0054] Various degrees of stringency of hybridization can be employed. The more stringent the conditions are, the greater the complementarity that is required for duplex formation. Stringency can be controlled by temperature, probe concentration, probe length, ionic strength, time, and the like. Hybridization experiments are often conducted under moderate to high stringency conditions by techniques well know in the art, as described, for example in Keller, G. H., and M. M. Manak (1987) DNA Probes, Stockton Press, New York, N.Y., pp. 169-170, hereby incorporated by reference. However, sequencing arrays typically use lower hybridization stringencies, as is known in the art.

[0055] Moderate to high stringency conditions for hybridization are known to the art. An example of high stringency conditions for a blot are hybridizing at 68° C. in 5×SSC/5× Denhardt's solution/0.1% SDS, and washing in 0.2×SSC/0.1% SDS at room temperature. An example of conditions of moderate stringency are hybridizing at 68° C. in 5×SSC/5× Denhardt's solution/0.1% SDS and washing at 42° C. in 3×SSC. The parameters of temperature and salt concentration can be varied to achieve the desired level of sequence identity between probe and target nucleic acid. See, e.g., Sambrook et al. (1989) vide infra or Ausubel et al. (1995) Current Protocols in Molecular Biology, John Wiley & Sons, NY, N.Y., for further guidance on hybridization conditions.

[0056] The melting temperature is described by the following formula (Beltz, G. A. et al., [1983]Methods of Enzymology, R. Wu, L. Grossman and K. Moldave [Eds.] Academic Press, New York 100:266-285).

Tm=81.5° C.+16.6 Log[Na+]+0.41(+G+C)−0.61(% formamide)-600/length of duplex in base pairs.

[0057] Washes can typically be carried out as follows: twice at room temperature for 15 minutes in 1×SSPE, 0.1% SDS (low stringency wash), and once at TM-20° C. for 15 minutes in 0.2×SSPE, 0.1% SDS (moderate stringency wash).

[0058] Nucleic acid useful in this invention can be created by Polymerase Chain Reaction (PCR) amplification. PCR products can be confirmed by agarose gel electrophoresis. PCR is a repetitive, enzymatic, primed synthesis of a nucleic acid sequence. This procedure is well known and commonly used by those skilled in this art (see Mullis, U.S. Pat. Nos. 4,683,195, 4,683,202, and 4,800,159; Saiki et al. [1985] Science 230:1350-1354). PCR is used to enzymatically amplify a DNA fragment of interest that is flanked by two oligonucleotide primers that hybridize to opposite strands of the target sequence. The primers are oriented with the 3′ ends pointing towards each other. Repeated cycles of heat denaturation of the template, annealing of the primers to their complementary sequences, and extension of the annealed primers with a DNA polymerase result in the amplification of the segment defined by the 5′ ends of the PCR primers. Since the extension product of each primer can serve as a template for the other primer, each cycle essentially doubles the amount of DNA template produced in the previous cycle. This results in the exponential accumulation of the specific target fragment, up to several million-fold in a few hours. By using a thermostable DNA polymerase such as the Taq polymerase, which is isolated from the thermophilic bacterium Thermus aquaticus, the amplification process can be completely automated. Other enzymes that can be used are known to those skilled in the art.

[0059] Polynucleotide sequences of the present invention can be truncated and/or mutated such that certain of the resulting fragments and/or mutants of the original full-length sequence can retain the desired characteristics of the full-length sequence. A wide variety of restriction enzymes that are suitable for generating fragments from larger nucleic acid molecules are well known. In addition, it is well known that Bal31 exonuclease can be conveniently used for time-controlled limited digestion of DNA. See, for example, Maniatis (1982) Molecular Cloning: A Laboratory Manual, Cold Spring Harbor Laboratory, New York, pages 135-139, incorporated herein by reference. See also Wei et al. (1983) J. Biol. Chem. 258:13006-13512. By use of Bal31 exonuclease (commonly referred to as “erase-a-base” procedures), the ordinarily skilled artisan can remove nucleotides from either or both ends of the subject nucleic acids to generate a wide spectrum of fragments that are functionally equivalent to the subject nucleotide sequences. One of ordinary skill in the art can, in this manner, generate hundreds of fragments of controlled, varying lengths from locations all along the original molecule. The ordinarily skilled artisan can routinely test or screen the generated fragments for their characteristics and determine the utility of the fragments as taught herein. It is also well known that the mutant sequences can be easily produced with site-directed mutagenesis. See, for example, Larionov, O. A. and Nikiforov, V. G. (1982) Genetika 18(3):349-59; and Shortle, D. et al., (1981) Annu. Rev. Genet. 15:265-94, both incorporated herein by reference. The skilled artisan can routinely produce deletion-, insertion-, or substitution-type mutations and identify those resulting mutants that contain the desired characteristics of wild-type sequences, or fragments thereof.

[0060] Thus, mutational, insertional, and deletional variants of the disclosed nucleotide sequences can be readily prepared by methods which are well known to those skilled in the art. These variants can be used in the same manner as the exemplified primer sequences so long as the variants have substantial sequence homology with the original sequence. As used herein, substantial sequence homology refers to homology that is sufficient to enable the variant polynucleotide to function in the same capacity as the polynucleotide from which the probe was derived. Homology is greater than 80%, greater than 85%, greater than 90%, or greater than 95%. The degree of homology or identity needed for the variant to function in its intended capacity depends upon the intended use of the sequence. It is well within the skill of a person trained in this art to make mutational, insertional, and deletional mutations that are equivalent in function or are designed to improve the function of the sequence or otherwise provide a methodological advantage.

[0061] Percent sequence identity of two nucleic acids may be determined using the algorithm of Karlin and Altschul (1990) Proc. Natl. Acad. Sci. USA 87:2264-2268, modified as in Karlin and Altschul (1993) Proc. Natl. Acad. Sci. USA 90:5873-5877. Such an algorithm is incorporated into the NBLAST and XBLAST programs of Altschul et al. (1990) J. Mol. Biol. 215:402-410. BLAST nucleotide searches are performed with the NBLAST program, score=100, wordlength=12, to obtain nucleotide sequences with the desired percent sequence identity. To obtain gapped alignments for comparison purposes, Gapped BLAST is used as described in Altschul et al. (1997) Nucl. Acids. Res. 25:3389-3402. When utilizing BLAST and Gapped BLAST programs, the default parameters of the respective programs (NBLAST and XBLAST) are used. See http://www.ncbi.nih.gov.

[0062] Standard techniques for cloning, DNA isolation, amplification and purification, for enzymatic reactions involving DNA ligase, DNA polymerase, restriction endonucleases and the like, and various separation techniques useful herein are those known and commonly employed by those skilled in the art. A number of standard techniques are described in Sambrook et al. (1989) Molecular Cloning, Second Edition, Cold Spring Harbor Laboratory, Plainview, N.Y.; Maniatis et al. (1982) Molecular Cloning, Cold Spring Harbor Laboratory, Plainview, N.Y.; Wu (ed.) (1993) Meth. Enzymol. 218, Part I; Wu (ed.) (1979) Meth. Enzymol. 68; Wu et al. (eds.) (1983) Meth. Enzymol. 100 and 101; Grossman and Moldave (eds.) Meth. Enzymol. 65; Miller (ed.) (1972) Experiments in Molecular Genetics, Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y.; Old and Primrose (1981) Principles of Gene Manipulation, University of California Press, Berkeley; Schleif and Wensink (1982) Practical Methods in Molecular Biology; Glover (Ed.) (1985) DNA Cloning Vol. I and II, IRL Press, Oxford, UK; Hames and Higgins (Eds.) (1985) Nucleic Acid Hybridization, IRL Press, Oxford, UK; Setlow and Hollaender (1979) Genetic Engineering: Principles and Methods, Vols. 1-4, Plenum Press, New York; and Ausubel et al. (1992) Current Protocols in Molecular Biology, Greene/Wiley, New York, N.Y. Abbreviations and nomenclature, where employed, are deemed standard in the field and commonly used in professional journals such as those cited herein.

[0063] Arrays can be printed on solid substrates, e.g., glass microscope slides. Before printing, slides are prepared to provide a substrate for binding, as known in the art. Arrays can be printed using any printing techniques and machines known in the art. Printing involves placing the probes on the substrate, attaching the probes to the substrate, and blocking the substrate to prevent non-specific hybridization, as known in the art.

[0064] Samples useful for analyses using the arrays of this invention include total RNA samples and m-RNA samples. RNA samples can be prepared as known in the art. An RNA sample is reverse transcribed into cDNA and simultaneously labeled, i.e. with one member of a two-color fluorescent system, such as Cy3-dCTP/Cy5-dCTP as known in the art. The arrays are hybridized with the prepared sample and washed at appropriate stringencies accounting for the choices of sample and probes of the array. The hybridization stringency can be higher when the probe sequence has higher homology with the gene it interrogates and when the probe is larger. A reference target, standard target, or other sample target for direct comparison may be prepared and hybridized simultaneously to the same array. A prepared sample will not degrade during hybridization and is labeled. Prepared samples are reverse transcribed and fluorescently labeled.

[0065] Hybridization results can be measured and analyzed using equipment and software available in the art. Before finalizing data, preliminary results are preferably normalized by methods known in the art. Analysis includes determination of statistical significance. Measurement may include normalization and analysis, including statistical analysis. Resulting data are typically stored in computer files.

[0066] Monoclonal or polyclonal antibodies, preferably monoclonal, specifically reacting with a protein of interest can be made by methods well known in the art. See, e.g., Harlow and Lane (1988) Antibodies: A Laboratory Manual, Cold Spring Harbor Laboratories; Goding (1996) Monoclonal Antibodies: Principles and Practice, 3rd ed., Academic Press, San Diego, Calif., and Ausubel et al. (1993) Current Protocols in Molecular Biology, Wiley Interscience/Greene Publishing, New York, N.Y.

[0067] Standard techniques for cloning, DNA isolation, amplification and purification, for enzymatic reactions involving DNA ligase, DNA polymerase, restriction endonucleases and the like, and various separation techniques are those known and commonly employed by those skilled in the art. A number of standard techniques are described in Sambrook et al. (1989) Molecular Cloning, Second Edition, Cold Spring Harbor Laboratory, Plainview, N.Y.; Maniatis et al. (1982) Molecular Cloning, Cold Spring Harbor Laboratory, Plainview, N.Y.; Wu (ed.) (1993) Meth. Enzymol. 218, Part I; Wu (ed.) (1979) Meth. Enzymol. 68; Wu et al. (eds.) (1983) Meth. Enzymol. 100 and 101; Grossman and Moldave (eds.) Meth. Enzymol. 65; Miller (ed.) (1972) Experiments in Molecular Genetics, Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y.; Old and Primrose (1981) Principles of Gene Manipulation, University of California Press, Berkley; Schleif and Wensink (1982) Practical Methods in Molecular Biology; Glover (ed.) (1985) DNA Cloning Vol. I and II, IRL Press, Oxford, UK; Hames and Higgins (eds.) (1985) Nucleic Acid Hybridization, IRL Press, Oxford, UK; Setlow and Hollaender (1979) Genetic Engineering: Principles and Methods, Vols. 1-4, Plenum Press, New York; and Ausubel et al. (1992) Current Protocols in Molecular Biology, Greene/Wiley, New York, N.Y. Abbreviations and nomenclature, where employed, are deemed standard in the field and commonly used in professional journals such as those cited herein.

[0068] The following examples are provided for illustrative purposes, and are not intended to limit the scope of the invention as claimed herein. Any variations in the exemplified articles which occur to the skilled artisan are intended to fall within the scope of the present invention.

[0069] Materials and Methods

[0070] Clinical material. Lymph node and lymphoma specimens were obtained from the University of Washington (UW) Hematopathology Laboratory tissue bank. Freshly excised tonsils were obtained from the Seattle Children's Hospital and Medical Center. All studies were approved by the University of Washington and Children's Hospital and Medical Center Institutional Review Boards. Between 1989 and 1996, lymph node and lymphoma specimens were surgically removed from patients in the course of their medical care at the UW Medical Center or one of several referral medical facilities in western Washington, Idaho, Montana, and Alaska. Tissues not needed for diagnostic testing were frozen in water-soluble tissue freezing medium (O.C.T.; Tissue-Tek, Naperville, Ill.) and transferred to a −70° C. freezer where they were maintained until processing. Each specimen was stripped of patient identifier information with the exception of final diagnosis and anatomic source and catalogued in a FileMaker Pro (FileMaker, Inc., Santa Clara, Calif.) database. From this frozen tissue archive, the following tissues were randomly selected: 18 benign reactive lymph node (RN), 21 grade I FL, 25 SLL, and 11 MCL specimens.

[0071] RNA Isolation and cDNA synthesis. Lymphoma and lymph node tissues were transferred on dry ice from −70° C. freezer to a −20° C. Tissue-Tek II Microtome/Cryostat. Using the cryostat, approximately fifty 10 μm tissue sections (representing ˜250 mg of tissue) were cut from each specimen and placed in a 15-mL conical tube on ice. Fresh tonsil specimens, each in ˜20 mL RPMI medium (Life Technologies, Rockville, Md.), were oriented in plastic petri dishes with the epithelium-containing side down. Using a plastic scalpel, the tissue was finely chopped against the underside of the epithelial layer to free lymphoid cells into the medium. The cells were pelleted by centrifugation for 20 minutes at 800×g in a room temperature IEC CentraCL centrifuge (International Equipment Company, Needham Heights, Mass.). A sufficient volume (typically 1-5 mL for lymphoma specimens and 5 mL for pelleted tonsil cells) of phenol/guanidine isothiocyanate (TRIzol; Invitrogen Life Technologies, Carlsbad, Calif.) was added. Samples were vortexed thoroughly and placed on ice for up to several hours. Total RNA was isolated according to the TRIzol manufacturer's instructions. Total RNA was quantified by spectrophotometry (J. Sambrook, E F Fritsche, and T Maniatis, Molecular Cloning A Laboratory Manual, Second Edition, Cold Spring Harbor Laboratory Press 1989, Plainview, N.Y. 11803; page E.5) using a Hewlett Packard 8452A Diode Array spectrophotometer (Hewlett Packard, Palo Alto, Calif.). Poly(A)+RNA was purified from total RNA using oligo(dT)₂₅-linked magnetic beads (Dynal, Oslo, Norway) according to manufacturer's instructions. Poly(A)+RNA was labeled with RiboGreen (Molecular Probes, Eugene, Oreg.) according to manufacturer's instructions and quantified using a Versafluor fluorometer (Bio-Rad Laboratories, Hercules, Calif.) by comparison to a standard curve generated using known concentrations of RNA (Molecular Probes). A typical yield from each ˜250 mg tissue specimen was 0.5-4 μg of poly (A)+RNA. Poly(A)+RNA from seven tonsils was pooled. poly(A)+RNA was analyzed using an Agilent 2100 bioanalyzer (Agilent Technologies, Palo Alto, Calif.). In each case, rRNA contamination was ≦14% and poly(A)+RNA migrated as a typical population of poly(A)+RNA species predominantly ranging in size from 1.3 to 4.4 kb (data not shown). Two labeled cDNA populations were prepared from each poly(A)+RNA pool. In one reaction, 2 μg poly(A)+RNA were reverse transcribed into cDNA labeled with Cy3-dCTP (AP Biotech, Little Chalfont, Buckinghamshire, United Kingdom) as previously described (Geiss GK JV 75:4321); in a second reaction, 2 μg poly(A)+RNA were reverse transcribed into cDNA labeled with Cy5-dCTP (AP Biotech). Labeled cDNAs were purified as previously described (Geiss GK JV 75:4321) and dissolved in 100 μl 10 mM Tris, pH 8.0. The efficiency of Cy3/Cy5-dCTP incorporation was determined using an HP 8452A diode array spectrophotometer (Hewlett Packard, Palo Alto, Calif.) and the following formulae:

A ₅₅₀×probe volume/0.15=pmol Cy3 probe, and

A ₆₅₀×probe volume/0.25=pmol Cy5 probe.

[0072] A typical yield for each Cy3-labeled cDNA was 100 pmol and for each Cy5-labeled cDNA was 75 pmol.

[0073] Microarray construction and hybridization. The spotted cDNA microarrays used in this study, containing ˜15,000 Homo sapiens sequence-verified Integrated Molecular Analysis of Genomes and their Expression (IMAGE) consortium clones (UniGene Build 19, plates 1 to 44; Lennon G Genomics 33:151) obtained from Research Genetics (Huntsville, Ala.), were obtained from the University of Washington (UW) Center for Expression Arrays (UW-CEA). These microarrays were constructed as described previously (Geiss GK JV 75:4321). Two sets of slides were used. Human HD-1 and HD-2 arrays each contained nearly unique sets of 7488 cloned human genes and ESTs spotted in duplicate. A complete list of the genes contained on these arrays is available at http://ra.microslu.washington.edu/Website/genelist/genelist.html. Each array was rinsed 10 times in sterile H₂O and then immediately dried using compressed air (Dust-Off, Falcon Safety Products, Branchburg, N.J.). Fluorescently labeled cDNAs were combined as described in the results section and concentrated by drying and were resuspended in 20 μL of hybridization solution (50% deionized formamide [Sigma, St. Louis, Mo.], 5×SSC [0.75M sodium chloride, 75 mM sodium citrate; Ambion, Austin, Tex.], 5×Denhardts solution [Fisher Scientific, Houston, Tex.], 0.1% sodium dodecyl sulfate [SDS; Ambion, Austin, Tex.], 100 μg/μL CotI DNA [Invitrogen], and 20 μg/μL polyA [5′-A(75)-3′] primer [Invitrogen]), denatured by boiling for 3 minutes, chilled on ice for 30 seconds, briefly centrifuged, and placed at room temperature. Labeled cDNAs were added to the each array and covered with 64- by 25-mm cover slips. Microarrays were hybridized for 14 to 16 hours at 42° C. in a humidified chamber (Genetix Limited, Hampshire, United Kingdom). Following hybridization, the microarrays were washed briefly in 1×SSC/0.2% SDS (pre-warmed to 54° C.) to remove the cover slips. The arrays were transferred to rectangular glass dishes (Wheaton Science Products, Millville, N.J.) in which they were washed by gentle rocking in 1×SSC/0.2% SDS (pre-warmed to 54° C.) for 10 minutes, 1×SSC/0.2% SDS (pre-warmed to 54° C.) for 10 minutes, 0.1×SSC/0.2% SDS (pre-warmed to 54° C.) for 10 minutes, 0.2×SSC (rt) for 1 minute, and 0.1×SSC (rt) for 1 minute. Finally, the arrays were dipped twice in distilled H₂O and dried with compressed air. The microarrays were scanned at 532 and 633 nm using a Molecular Dynamics Avalanche dual-laser confocal scanner.

[0074] Microarray data analysis. Duplicate Human HD1 and HD2 slides were hybridized with the same cDNAs but with the fluorescent labels reversed to dampen dye-specific effects (Methods 24: 289 AK Kenworthy; Ramdas L Genome Biol 2001;2(11):RESEARCH0047). Each slide contained two identical sets of spots on sides A and B of the slide. Two images, corresponding to sides A and B, were obtained for each slide. Using Spot-On software developed at the UW Center for Expression arrays (Geiss GK JV 75:4321; http://ra.microslu.washington.edu/Website/analysis/analysis.html), the intensity of each spot (subtracted for local background) in both channels was obtained from each image and exported as a text file. The Spot-On software program divides each spot into four quadrants and provides the average signal intensity for each quadrant as well as the background signal intensity surrounding the spot. Using GeneSifter.Net™ (VizX Labs, Seattle, Wash.), the intensity value of each spot in an image was normalized to the mean intensity of all spots in that image. Clones were selected if the mean spot intensities showed ≧4-fold differential expression in pairwise comparisons among RN, FL, MCL, and SLL tissues and showed a corresponding p-value of ≦0.05 (derived from Student t-test analysis).

[0075] qRT-PCR. 40 μL PCR mixtures contained 1× AmpliTaq Gold Buffer (Applied Biosystems, Foster City, Calif.), 4 mM MgCl₂, 0.025 U/μL AmpliTaq Gold (Applied Biosystems), 0.25 U/μL Moloney leukemia virus reverse transcriptase (Invitrogen, Carlsbad, Calif.), 0.4 U/μL RNase inhibitor (Invitrogen), 0.5 μg/μL BSA (Ambion, Austin, Tex.), 0.33× SYBR Green I (obtained as a 10,000× solution from Molecular Probes, Eugene, Oreg.), 0.8 μM passive reference DNA oligohexamer, 5′-(6-carboxyrhodamine)-GATTAG-PO₄-3′ (Rox Standard I, Synthegen, Houston, Tex.), 200 μM dNTPs (Amersham Biosciences, Piscataway, N.J.), 50 nM gene-specific primers (Invitrogen), and 5 ng poly(A)+RNA. For qRT-PCR validation of array results (FIGS. 3 and 4), an equal amount of poly(A)+RNA was pooled from multiple specimens as described in the footnote of Table 1. For qRT-PCR analysis of individual specimens (FIG. 5), variable amounts (≦5 ng) of poly(A)+RNA were used since 5 ng were not available for all cases; subsequently, the level of cyclin D1, 13cDNA73, and KIAA1407 poly(A)+RNA was normalized to the level of expression of cyclophilin. Gene-specific primers were designed using the computer program Primer Express 1.5 (Applied Biosystems) using default settings for RT-PCR primer selection. Using an ABI 7700 sequence detector (Applied Biosystems), the reactions were subjected to the following cycling conditions: 30 min at 48° C., 10 min at 95° C., and 40 cycles comprised of 15 seconds at 95° C. and 1 minute at 60° C. SYBR Green I is fluorescent when bound to double-stranded DNA. Messenger RNA can be semi-quantified based on the assumption that amplicon concentration doubles with each round of PCR [Wittner et al Clin Chem 48:1178]. Samples with a high poly(A)+RNA copy number, subjected to RT-PCR, produce a threshold level of fluorescent signal after fewer PCR cycles (Ct, or cycle number resulting in threshold fluorescent signal) than samples with a low poly(A)+RNA copy number. Thus, the relative amount of poly(A)+RNA in two samples, sample 1 and sample 2, can be semi-quantified based on the following formula:

([RNA] _(Sample 1) /[RNA] _(Sample 2)) ≈E ^((Ct Sample 2−Ct Sample 1))≈2^((Ct Sample 2−Ct Sample 1)),

[0076] where E is PCR efficiency (approximately 2 in exponential phase).

[0077] Results

[0078] cDNA array analysis. cDNA microarrays constructed at the UW-CEA were used to identify genes that differ in expression among RN, FL, MCL and SLL specimens. These arrays contained duplicate spots of PCR-amplified insert cDNAs from 14,976 sequence verified IMAGE clones (G Lennon Genomics 33:151) representing ˜13,500 individual UniGene clusters. Poly(A)+RNA was purified from archival tissue specimens that had been frozen shortly after their surgical removal and maintained at −70° C. For array analysis, equal amounts of poly(A)+RNA from multiple specimens representing the same tissue type were pooled. Poly(A)+RNA from 17 RN specimens was pooled to generate a single pool of RN poly(A)+RNA. Similarly, poly(A)+RNA from 14 Grade I FL specimens, 12 MCL specimens, and 16 SLL specimens was pooled. Cy3- and Cy5-labeled first-strand cDNA was generated from each poly(A)+RNA pool. Additionally, Cy3- and Cy5-labeled tonsil cDNA was generated for use as a reference cDNA population. Sample and reference cDNAs were combined and hybridized to microarrays. All array experiments were done in duplicate where the labeling scheme was reversed to compensate for potential dye-specific incorporation effects and for dye-dependent non-linearity in signal intensity (Methods 24: 289 AK Kenworthy; Ramdas L Genome Biol 2001;2(11):RESEARCH0047). For example, Cy3-labeled lymphoma cDNA and Cy5-labeled tonsil cDNA were hybridized to one array whereas Cy5-labeled lymphoma cDNA and Cy3-labeled tonsil cDNA were hybridized to a second array. After hybridization, microarray slides were washed under conditions of increasing stringency and scanned in the Cy3 and Cy5 channels using a laser confocal scanner.

[0079] Signal and local background intensities were quantified for each spot using the Spot-On software package developed at the UW-CEA. At least four separate measurements were obtained for each IMAGE clone. Since the vast majority of IMAGE clones were spotted in duplicate and since two arrays per sample were used, four measurements were obtained for most clones. However, some image clones were spotted more than twice per array; alternatively, some genes were represented by more than one IMAGE clone. In these cases, more than four measurements were obtained. The mean (+/− standard error of the mean) expression intensity was calculated based on all available intensity measurements for each gene represented on the array. Ninety-one genes that were ≧4-fold differentially expressed (p≦0.05 based on t-test analysis) between any two tissue types were selected by pairwise analysis using the GeneSifter™ array data analysis program (VizX Labs, LLC, Seattle, Wash.). 39 of these genes were differentially expressed in two or more pairwise comparisons (FIG. 1). 8, 11, 6, 12, 4, and 11 genes were uniquely differentially expressed between RN and FL, RN and MCL, RN and SLL, FL and MCL, FL and SLL, and MCL and SLL, respectively (FIG. 2). Table 1 lists the genes, IMAGE clone numbers, representative accession numbers, chromosomal locations, and functional information for these 120 genes.

[0080] Validation of array results using qRT-PCR. The confirmatory method of qRT-PCR with SYBR Green I dye detection (M Rajeevan J Mol Diag 3:26) was used to quantify the relative RNA expression for a subset of 38 of the 120 genes. qRT-PCR was performed in duplicate on pooled poly(A)+RNA from multiple RN, FL, MCL, or SLL specimens. A general analysis of the present array and qRT-PCR data is depicted in FIG. 3. Data for 4 genes (10% of 39) genes was not informative due to lack of amplification or high no-RT background signal. Of the remaining 35 genes, 23 (66% of 35) were found by qRT-PCR to be ≧2-fold differentially expressed in the same direction as the microarray data and to give amplicons that migrated as a single band of expected size by polyacrylamide gel electrophoresis (data not shown). FIG. 4 compares the array and qRT-PCR results for these 23 genes in pseudocolor graphics where the expression level of each gene in RN, FL, MCL, and SLL is displayed as a ratio of its expression level relative to the reference RNA (tonsil) pool.

[0081] qRT-PCR analysis of gene expression in individual specimens. Pooled poly(A)+RNA was used to identify and confirm differential gene expression patterns. The level of expression of selected genes in individual specimens was also investigated. qRT-PCR was performed in duplicate for several genes of interest for 10 RN specimens, 9 FL specimens, pooled tonsil RNA, 10 MCL specimens, and 10 SLL specimens. Data for one of the MCL specimens (MCL-14) were discarded due to high amplification signals in no-RT controls (data not shown). Selected results for the remaining specimens are shown in FIG. 5. As expected, cyclin D1 was more highly expressed in all MCL specimens than in any other specimens (FIG. 5A). There was considerable variability (˜6-fold range) in cyclin D1 expression in individual MCL cases. 13cDNA73 was not appreciably expressed in RN, MCL, or tonsil, but was variably expressed in FL specimens (˜16 fold range) and SLL specimens (˜80 fold range) (FIG. 5B). KIAA1407 was not appreciably expressed in RN, FL, or tonsil, but there was variable expression in MCL specimens (˜21 fold range) and SLL specimens(˜20-fold range) (FIG. 5C).

[0082] Using cDNA microarray analysis, 120 genes whose expression patterns appear to distinguish among RN, FL, MCL, and SLL have been identified. The differential expression patterns of 23 of these genes were validated using the complementary approach of quantitative RT-PCR. This list includes genes previously known to be differentially expressed in LGBCL, genes known to be involved in cancer types other than lymphoma, genes not previously associated with malignancy, and partially characterized genes/ESTs of unknown function.

[0083] The results herein largely do not confirm previously published results obtained using oligonucleotide microarrays to examine gene expression in RN and MCL (Hofmann, de Vos et al. 2001) In that study, 92 genes were identified to be ≧3-fold differentially expressed between MCL and RN (Hofmann, de Vos et al. 2001). The cDNA arrays used herein contained probes for 55 of these genes. However, the results herein showed that only 11 (20%) of these 55 genes were significantly (p≦0.05) differentially expressed between RN and MCL and that, among these genes, only cyclin D1 showed ≧3-fold differential expression (data not shown). The reason for discrepancy between the present data set and these published results is unclear. However, a recent report suggests that microarray data obtained using oligonucleotide and cDNA array platforms may not be directly comparable (Kuo, Jenssen et al. 2002).

[0084] The differential expression of several genes previously known to be involved in LGBCL was validated. The finding that cyclin D1 was significantly over-expressed in MCL was not surprising since the expression of this cell cycle regulatory protein is known to be involved in MCL pathogenesis (Tsujimoto, Yunis et al. 1984) (Tsujimoto, Jaffe et al. 1985). By qRT-PCR analysis of individual cases considerable variability (˜6-fold range) in cyclin D1 expression in individual MCL cases was found. Variable expression levels of cyclin D1 in MCL specimens have also been obtained by other researchers using qRT-PCR (Specht, Kremer et al. 2002) (Elenitoba-Johnson, Bohling et al. 2002). This variability may reflect different proportions of neoplastic cells within tissue specimens sampled or an underlying difference in the neoplastic cells themselves. A transcript binding to a v-jun cDNA probe was significantly over-expressed in MCL relative to FL. The transcript was presumably c-jun since the amplicon generated in qRT-PCR analysis using primers directed against c-jun sequence was of a size expected from the c-jun sequence (data not shown). c-Jun is an AP-1 transcription factor component known to be over-expressed in the malignant Reed-Sternberg cells that characterize Hodgkin's disease (Mathas, Hinz et al. 2002). c-Jun was recently found by array analysis to be over-expressed in MCL relative to RN (Hofmann, de Vos et al. 2001). Lastly, we found that BCL-2 was significantly over-expressed in SLL versus RN and was over-expressed in FL versus RN, although not at the p<0.05 level of significance (data not shown). Since BCL-2 is known to be involved in the pathogenesis of FL and SLL (Hockenbery, Nunez et al. 1990) (Vaux, Cory et al. 1988), we expected to identify this gene as being over-expressed in these specimen types.

[0085] Several of the genes identified have well-established roles in cancer types other than lymphoma. A transcript binding to the v-myb cDNA probe (presumably c-myb since the qRT-PCR product was of size expected for c-myb [data not shown]) was significantly under-expressed in MCL versus SLL. c-myb is a member of the myb family of transcription factors that regulate the proliferation, differentiation, and apoptosis of hematopoietic cells and are frequently over-expressed in human myeloid and lymphoid leukemias (Davies, Badiani et al. 1999). c-myb expression in LGBCL lymphomas is believed to not have been previously studied. DNA methyltransferase 3A (DNMT3A) was significantly over-expressed in MCL relative to FL and CLL. DNMT3A and DNMT3B are thought to establish cytosine methylation patterns that influence the expression of genes containing upstream CpG islands (Jones and Laird 1999). DNA from malignant cells often shows global hypomethylation but localized CpG island hypermethylation resulting in the down-regulated expression of tumor suppressor genes (Melki and Clark 2002). DNMT over-expression may contribute to altered DNA methylation patterns in cancer and CLL cells were recently shown to have increased DNMT3A expression relative to normal lymphocytes (Melki and Clark 2002). However, no published studies have directly compared methylation patterns between FL, MCL, and SLL.

[0086] The expression patterns of several of the genes identified have been studied in cancer but have no known role in carcinogenesis. CD69 was over-expressed in MCL relative to RN. CD69 is best known as a T lymphocyte antigen and was previously shown to be expressed by benign activated B lymphocytes as well as by malignant FL, MCL, and SLL cells (Erlanson, Gronlund et al. 1998). However, a role for CD69 in lymphoma is unclear and the findings may be explained by the expression of this gene product in T cells contained within lymphoma specimens. We found that keratin 5 was under-expressed in FL and MCL relative to RN. Keratin 5 is not normally expressed in lymphocytes but are expressed in lymph node reticular cells (Doglioni, Dell'Orto et al. 1990). Decreased keratin 5 expression in lymphoma may reflect replacement of the normal lymph node architecture with neoplastic cells. We found that crystallin mu was over-expressed in MCL relative to RN and FL. Crystallin mu was originally cloned as a structural component of kangaroo lens (Kim, Gasser et al. 1992) and was more recently cloned as a nicotinamide-adenine dinucleotide phosphate-regulated thyroid hormone binding protein (Vie, Evrard et al. 1997). The role of this protein in lymphoma is unclear. A previous study of thyroxine (T3) and triiodothyronine (T4) metabolism in a small number of euthyroid patients with lymphoma and other hematopoietic disorders found that these patients showed increased levels of T3/T4 per body mass unit (Kirkegaard, Hasselbalch et al. 1989). This result suggests that hematopoictic tumors contain concentrated thyroid hormone binding sites. Over-expressed crystallin mu may serve as a T3/T4 sink in lymphoma patients.

[0087] Several of the genes identified are partially characterized genes/expressed sequence tags (ESTs) of unknown function. IMAGE:293005 was over-expressed in RN and FL relative to MCL and SLL. This gene shares 72% identity over ˜460 nucleotides with a mouse homologue (encoding the murine M17 protein) which is known to be highly expressed in the germinal centers of mice (Christoph, Rickert et al. 1994). Because RN specimens contain expanded germinal centers and FL specimens are largely comprised of neoplastic cells of germinal center origin, the expression patterns identified are consistent with germinal expression of IMAGE:293005. Further, this gene falls within the germinal center cluster identified by Alizadeh and colleagues through the microarray-based analysis of a large number of normal and malignant lymphocyte samples (Alizadeh, Eisen et al. 2000) (data not shown).

[0088] 13cDNA73 was brightly over-expressed in SLL and moderately over-expressed in FL relative to RN and MCL. Individual case qRT-PCR analysis showed that expression of this gene product varied markedly among SLL (˜80 fold range) and FL (˜16 fold range) specimens. KIAA1407 was over-expressed in MCL and SLL relative to RN and FL. QRT-PCR analysis of individual cases showed that expression varied markedly among MCL (˜˜21 fold range) and SLL (˜16 fold range).

[0089] Although this description contains many specificities, these should not be construed as limiting the scope of the invention, but as merely providing illustrations of some of the preferred embodiments of the invention. All references cited herein are hereby incorporated by reference to the extent not inconsistent with the disclosure herewith. TABLE 1 120 Genes Identified by cDNA Microarray Analysis¹ to be Differentially Expressed (≧4-Fold, p ≦ 0.05) among RN, FL, MCL, and SLL¹ I.M.A.G.E. Clone Representative Chromosomal qRT-PCR Gene Number(s) Function Sequence Location Results Forward Primer Reverse Primer 13CDNA73 EST 46284 Unknown NM_023037 13q13.3 Confirmed² GATGACGACAGG TGACCAGGACTG CCGATGATT CGTTCCATT SEQ ID NO: 224 SEQ ID NO: 225 ABCG2 ATP-binding 288736 Small NM_004827 4q22 ND cassette, sub- Molecule family G Transport ACTN4 Actinin, alpha 4 140951 Cytoskeleton NM_004924 19q13 ND ALOX5 Arachidonate 5- 179890 Immune NM_000698 10q11.2 ND lipoxygenase ANXA1 Annexin A1 208718 Immune NM_000700 9q12-q21.2 ND APEH N- 813279 Metabolism NM_001640 3p21 ND acylaminoacyl- peptide hydrolase APOC2 Apolipoprotein 809523 Metabolism NM_000483 19q13.2 Confirmed³ CCCGCTGTAGAT TCTCCCTTCAGC C-II GAGAAACTCA ACAGAAAGAA SEQ ID NO: 226 SEQ ID NO: 227 APOD Apolipoprotein 159608 Metabolism NM_001647 3q26.2-qter ND D ATF4⁴ Activating 949971 Gene NM_001675 22q13.1 ND transcription Expression factor 4 Regulation BACH2 BTB and CNC 296483 Unknown NM_021813 6q15 ND homology 1, basic leucine zipper transcription factor 2 BCL2⁵ B-cell 232714 Apoptosis NM_000633 18q21.3 Confirmed³ ATGACTGAGTAC CAGAGACAGCC CLL/lymphoma CTGAACCGGC AGGAGAAATCA 2 SEQ ID NO: 228 SEQ ID NO: 229 C1ORF29 Chromosome 1 754479 Unknown NM_006820 1p31.1 ND open reading frame 29 C7ORF10 Chromosome 7 309499 Unknown NM_024728 7p15.2 ND open reading frame 10 CAT56⁵ Guanine 60201 Unknown NM_025263 6p21.3 ND nucleotide binding protein- like 1 CCL28 Chemokine(C-C 136919 Immune NM_019846 5p12 ND motif) ligand 28 CCL4⁴ Chemokine (C-C 205633 Immune NM_002984 17q12 Confirmed² CCAGCTGTGGTA TGAGCAGCTCAG motif) ligand 4 TTCCAAACCA TTCAGTTCCA SEQ ID NO: 230 SEQ ID NO: 231 CCNA2⁵ Cyclin A2 950690 Cell NM_001237 4q25-q31 Confirmed² GCTGGCCTGAAT GCATGCTGTGGT Signalling CATTAATACG GCTTTGA SEQ ID NO: 232 SEQ ID NO: 233 CCND1 Cyclin D1 841641 Cell Cycle NM_053056 11q13 Confinned² AGGTCTGCGAGGA TGCAGGCGGCTC Regulation ACAGAAGTG TTTTTCA SEQ ID NO: 234 SEQ ID NO: 235 CD209L CD209 antigen- 782758 Metabolism NM_014257 19p13 Not Confirmed³ TGCTGCAACTCCT CGTCTTGCTCGG like DC-SIGNR CTCCTTCAT ATTGTTCCT SEQ ID NO: 236 SEQ ID NO: 237 CD69 CD69 antigen 704459 Immune NM_001781 12p13-p12 Confirmed³ CATGGTGCTACTC CCCTGTAACGTT TTGCTGTCA GAACCAGTTG SEQ ID NO: 238 SEQ ID NO: 240 CD86 CD86 antigen 50214 Immune NM_006889 3q21 Not Confirmed² GGAAAAGACATC TCTGGTTGTGGT AACCCCCATA CTCTGGTGTT SEQ ID NO: 241 SEQ ID NO: 242 CDC2 Cell division 898286 Cell Cycle NM_001786 10q21.1 ND cycle 2, G1 to S Regulation and G2 to M CDCA7 c-Myc target 244058 Unknown NM_031942 2q31 ND JPO1 CEACAM6 Carcinoembryonic 509823 Cell NM_002483 19q13.2 ND antigen- Signalling related cell adhesion molecule 6 CLCN4 Chloride channel 363058 Small NM_001830 Xp22.3 High No-RT GCGGCACTGCAG TTCCCTTAGCCA 4 Molecular Control² GTGTAATTA GTCGATGGT Transport SEQ ID NO: 243 SEQ ID NO: 244 COL24A1 Collagen type 280567 Extracellular NM_152890 1 ND XXIV, alpha 1 Matrix CPNE1 Copine I 843139 Unknown NM_003915 20q11.21 Not Confirmed³ CTGCCTCGCAAT CCACACCCACAA ACTTCATGCT TGATCACTGA SEQ ID NO: 245 SEQ ID NO: 246 CRYM Crystallin, mu 42373 Unknown NM_001888 16p13.11- Confirmed² GGCAGGTGCAGA TGGCTCCAACAG p12.3 TGTGATCAT CATTGATG SEQ ID NO: 247 SEQ ID NO: 248 CSDA Cold shock 810057 Gene NM_003651 12p13.1 ND domain protein Expression A Regulation CTCF CCCTC-binding 240367 Gene NM_006565 16q21- Discordant² CACACAGGTACT TCGCACATGGAA factor (zinc Expression q22.3 CGTCCTCACA CACTTGAA finger protein) Regulation SEQ ID NO: 249 SEQ ID NO: 250 DKFZP434P0531 EST 325024 Unknown BC022095 6p21.3 ND DKFZP564B1162⁵ EST 418185 Unknown NM_031305 4q21.23- ND g21.3 DNMT3A DNA (cytosine- 202514 Gene AF331856 2p23 Confirmed³ CCATTCCTGGTCA TCCTGTGTGGTA 5-)- Expression CGCAAAAC GGCACCTGAA methyltransferase Regulation SEQ ID NO: 251 SEQ ID NO: 252 3 alpha EST EST 47151 Unknown R48935 ND (IMAGE:47151) EST EST 53092 Unknown BG284034 2 ND (IMAGE:53092) EST EST 110582 Unknown T90074 11 ND (IMAGE:110582) EST EST 121977 Unknown T97780 ND (IMAGE:121977) EST EST 122702 Unknown BC034319 ND (IMAGE:122702) EST EST 122723 Unknown AA777690 ND (IMAGE:122723) EST EST 127710 Unknown AA579610 10 ND (IMAGE:127710) EST EST 130742 Unknown H13708 ND (IMAGE:130742) EST EST 133613 Unknown R30836 ND (IMAGE:133613) EST EST 136909 Unknown BU162571 ND (IMAGE:136909) EST EST 193771 Unknown BQ322085 11 ND (IMAGE:193771) EST EST 201981 Unknown BC025340 6 Confirmed³ CCGTCTGTCTCCT TCCTGTCCTCTGCT (IMAGE:201981) TTCCTTCTG CTGTGGAT SEQ ID NO: 253 SEQ ID NO: 254 EST EST 203114 Unknown BF431502 ND (IMAGE:203114) EST EST 204740 Unknown H57305 ND (IMAGE:204740) EST EST 234376 Unknown AK097411 ND (IMAGE:234376) EST EST 258118 Unknown N27108 7 Discordant³ TGCTCCCCTGTTT TCCTGGAAGTAAT (IMAGE:258118) TTGTGACA GCCAACTCA SEQ ID NO: 255 SEQ ID NO: 256 EST EST 258242 Unknown BE786990 1 ND (IMAGE:258242) EST EST 265294 Unknown N20848 ND (IMAGE:265294) EST EST 278944 Unknown AL121338 ND (IMAGE:278944) EST EST 284584 Unknown N59450 ND (IMAGE:284584) EST EST 287721 Unknown N79323 ND (IMAGE:287721) EST EST 293005 Unknown NM_152785 3 Confirmed² GGCCTAGAGCCT TTGCTCCTCTCACT (IMAGE:293005) CTTGATTCAA CCATGTGT SEQ ID NO: 257 SEQ ID NO: 258 EST EST 294647 Unknown BE971364 ND (IMAGE:294647) EST EST 305302 Unknown BM906531 3 ND (IMAGE:305302)⁵ EST EST 325247 Unknown BU630466 17 ND (IMAGE:325247) EST EST 341096 Unknown BM546103 15 ND (IMAGE:341096)⁵ EST EST 382773 Unknown AA065090 ND (IMAGE:382773)⁵ EST EST 429165 Unknown BF677678 11 ND (IMAGE:429165)⁵ EST EST 429569 Unknown AI248013 19 ND (IMAGE:429569) EST EST 503051 Unknown BU630466 17 ND (IMAGE:503051) EST EST 564567 Unknown AA127395 3 ND (IMAGE:564567) EST EST 626199 Unknown BG283145 7 ND (IMAGE:626199) FGR Gardner-Rasheed 681906 Cell NM_005248 1p36.2- ND feline sarcoma Signalling p36.1 viral (v-fgr) oncogene homolog FLJ14105 EST 742904 Unknown BQ070901 2 ND FU21562 EST 212772 Unknown NM_025113 13q14.11 Confirmed² CAGCTGGCTCGAT TCTAGGAGGAGCCC AGTCGTAAA AGTCTTCA SEQ ID NO: 259 SEQ ID NO: 260 FLJ22557 EST 501778 Unknown NM_024713 15q13.1 ND FMOD Fibromodulin 811162 Extracellular NM_002023 1q32 ND Matrix FREB Fc receptor 290749 Immune NM_032738 1q23.1 ND homolog GBA2 Glucosidase, beta 796297 Metabolism NM_020944 9p11.2 ND (bile acid) 2 GM2A GM2 ganglioside 795173 Metabolism NM_000405 5q31.3- Confirmed³ AAAAGCCATCCCA CACATTTCCAGGAA activator protein q33.1 GCTCAGTAG CGACGAT SEQ ID NO: 261 SEQ ID NO: 262 GPM6A Glycoprotein 784910 Plasma NM_005277 4q34 ND M6A Membrane Protein GS3955⁵ GS3955 protein 813426 Cell NM_021643 2p25.1 Primer Dimer³ AGGAGCTGGTGTG CCCCATAGCTTCGC Signalling CAAGGTGTT TCAAAGAA SEQ ID NO: 263 SEQ ID NO: 264 H11 Protein kinase 205049 Unknown NM_014365 12q24.23 ND H11 IGHG3 Immunoglobulin 289337 Immune BC019046 14q32.33 Confirmed² GCAGCCGGAGAAC TGCATCACGGAGCA heavy constant AACTACAAG TGAGAA gamma 3 SEQ ID NO: 265 SEQ ID NO: 266 IGJ Immunoglobulin J 80948 Immune NM_144646 4q21 High No-RT TCCCATGGCAAGT CCATGACACAGCCA polypeptide Control² CCTAAAGC AACAGAAA SEQ ID NO: 267 SEQ ID NO: 268 IL15RA⁴ Interleukin 15 488019 Immune NM_002189 10p15-p14 ND receptor, alpha IL16⁴ Interleukin 16 809776 Immune NM_004513 15q26.3 ND (lymphocyte chemoattractant factor) IL24 Interleukin 24 712049 Apoptosis NM_006850 1q32 Not Confirmed³ TCTCATCGTGTCAC GAGCTGCTTCTACG AACTGCAA TCCAACTG SEQ ID NO: 269 SEQ ID NO: 270 IL4R⁴ Interleukin 4 714453 Immune NM_000418 16p11.2- Confirmed³ CAGCGTTTCCTGCA GACCCCTGAGCATC receptor 12.1 TTGTCATC CTGGATTA SEQ ID NO: 271 SEQ ID NO: 272 ING1³ Inhibitor of 810061 Gene NM_005537 13q34 ND growth family, Expression member 1 Regulation ITM3 Integral 471196 Plasma NM_030926 2q37 Confirmed² GGAGCTCCTCATG AGGTGTCTTTCCCG membrane protein Membrane AACGTGAA TTGCA 3 Protein SEQ ID NO: 273 SEQ ID NO: 274 JUN⁴ v-Jun sarcoma 358531 Gene NM_002228 1p32-p31 Confirmed² CTAACGCAGCAGT TCTCCGTCGCAACT virus 17 oncogene Expression TGCAAACA TGTCAA homolog Regulation SEQ ID NO: 275 SEQ ID NO: 276 KIAA0125 EST 210368 Unknown NM_014792 14q32.33 High No-RT ATGGCTCCTGCTGT GTGAAGCGGTGGAC Control^(2.) ACCTCAAG AAGAAACT SEQ ID NO: 277 SEQ ID NO: 278 KIAA0172 EST 812975 Unknown D79994 9p24.3 ND KIAA0355⁵ EST 784104 Unknown NM_014686 19q13.12 KIAA1111 EST 810621 Unknown AB029034 X KIAA1276⁵ EST 417637 Unknown BQ722784 4 ND KIAA1350 EST 321886 Unknown AB037771 4q28.1 Confirmed² CGAAGCTGTTGTTC GGCTGGTGTAGCAG GGAATC ATCATACC SEQ ID NO: 279 SEQ ID NO: 280 KIAA1407 EST 121475 Unknown AF509494 3q13.31 Confirmed² AACCTGCCAGATG CGGTGTCATCAATT CTTGTGAAT GCTTTGG SEQ ID NO: 281 SEQ ID NO: 282 KLF4 Kruppel-like 188232 Gene NM_004235 9q31 Discordant³ GCTCCATTACCAA GTGCCTGGTCAGTT factor 4 Expression GAGCTCATG CATCTGA Regulation SEQ ID NO: 283 SEQ ID NO: 284 KRT19 Keratin 19 810131 Cytoskeleton NM_002276 17q21 Primer Dimer² GCATGAAAGCTGC CCTGATTCTGCCGC CTTGGAA TCACTATC SEQ ID NO: 285 SEQ ID NO: 286 KRT5 Keratin 5 592540 Cytoskeleton NM_000424 12q12-q13 Confirmed³ CAGAAGCCGAGTC TGGCGCACTGTTTC CTGGTATCA TTGACA SEQ ID NO: 287 SEQ ID NO: 288 LEF1 Lymphoid 347036 Gene NM_016269 4q23-q25 ND enhancer-binding Expression factor 1 Regulation LOC51290⁵ EST 259902 Unknown NM_016570 12p12.1 Not Confirmed³ AGCAGAAAGAGTG TTGGTGGAAGAGCT GCAGAGGAT GTTGATGT SEQ ID NO: 289 SEQ ID NO: 290 LOC55971 Insulin receptor 131318 Cell NM_018842 7q11.21 ND tyrosine kinase Signalling substrate LOC87769 EST 781088 Unknown BC001077 13q32.3 ND LOC91937 EST 202315 Unknown NM_138379 5q33.2 ND MAGP2⁵ Microfibril- 138496 Cytoskeleton NM_003480 12p13.1- ND associated p12.3 glycoprotein-2 MGC15437 NM23- 489047 Unknown NM_032873 11q24.1 Confirmed² GGTGGATCTGTCA GCCTGTCACCTCAG phosphorylated GCTGCCATA AACTCCAA unknown SEQ ID NO: 291 SEQ ID NO: 292 substrate MGC4174 Hypothetical 126450 Unknown NM_024319 1q42.13 ND protein MGC4174 MYBL2 v-Myb 815526 Gene NM_002466 20q13.1 Confirmed² CCCATCAAGAAAG GCAGTTGTCGGCAA myeloblastosis Expression TCCGGAAGT GGATAGA viral oncogene Regulation SEQ ID NO: 293 SEQ ID NO: 294 homolog (avian)- like 2 NFE2L2⁴ Nuclear factor 884438 Gene NM_006164 2q31 ND (erythroid-derived Expression 2)-like 2 Regulation NUDT4P2 EST 123735 Unknown AU142060 9 ND OSBPL10⁵ Oxysterol binding 135608 Metabolism NM_017784 3p22.3 ND protein-like 10 OSF-2 Osteoblast 897910 Cell NM_006475 13q13.2 ND specific factor 2 Adhesion PPP3R2 Protein 782141 Cell NM_147180 ND phosphatase 3, Signalling regulatory subunit B, beta isoform RIPK1 Receptor 592125 Apoptosis NM_003804 6p24.3 ND (TNFRSF)- interacting serine- threonine kinase 1 RNASE1 Ribonuclease, 840493 Metabolism NM_002933 14q11.1 Not Confirmed² TCCACTGCATCATT TCTCCAAAGCGAGG RNase A family, CAGCTTTC TCTTCCT 1 (pancreatic) SEQ ID NO: 295 SEQ ID NO: 296 SENP3 Sentrin/SUMO- 128506 Unknown NM_015670 17p13 ND specific protease 3 SERPINE2⁵ Serine (or 246722 Extracellular NM_006216 2q33-q35 ND cysteine) Matrix proteinase inhibitor, clade E, member 2 SF1⁴ Splicing factor 1 809648 Gene NM_004630 11q13 Not Confirmed² AGCTCAGAGACCC ACTGAGGATCACCA Expression GCAGCATTA GGCCTTTTG Regulation SEQ ID NO: 297 SEQ ID NO: 298 SLC13A3⁵ Solute carrier 51406 Metabolism NM_022829 20q12- ND family 13, q13.1 member 3 SLC2A3⁵ Solute carrier 121981 Metabolism NM_006931 12p13.3 Confirmed³ GCCCATCATCATTTC TGAACACCTGCAT family 2, member CATTGTG CCTTGAAGA 3 SEQ ID NO: 299 SEQ ID NO: 300 UniGene TFAP2C Transcription 725680 Gene NM_003222 20q13.2 High No-RT TCGCAAAGGTCCCA CGTAGAGCTGAGG factor AP-2 Expression Control² TTTCC AGCGACAAT gamma Regulation SEQ ID NO: 301 SEQ ID NO: 302 TNFRSF12⁵ Tumor necrosis 345586 Apoptosis AB018263 1p36.2 ND factor receptor superfamily, member 12 UBE2D2⁵ Ubiquitin- 773617 Metabolism NM_003339 5q31.3 ND conjugating enzyme E2D 2 ZNF363⁵ Zinc finger 784218 Gene NM_015436 4q21.1 ND protein 363 Expression Regulation #MCL specimens (MCL-1, MCL-2, MCL-3, MCL-6, MCL-7, MCL-8, MCL-9, MCL-10, MCL-11), and 25 SLL specimens (SLL-1, SLL-2, SLL-3, SLL-4, SLL-5, SLL

[0090] TABLE 2 Theoretical end of UniGene insert with IMAGE Clone Accession respect to SEQ ID NO # # poly A tail Sequence GCTATAACATGGCAGCCTCGCATCCCTTCCTGCTTACCACCTTT CTAGATATTAAGGCTTACTTAGTTCTTACTGAATTAAATGGAGA GTGACTTGACAACTCTTGGCCAGCCATTCTTAATGATATTTGTG TTCCTAAGATATAGCAGTATCTGCAAATCCTAAATCTGTCTCAT GAAGATTTTATGATCTTTTAGATCAGTGATTAATGGGAAGGACA ATGTCCTTTATTTTTTTAAATAAAAAATAATGACCTGGAACTTT CTCTGTAGGCCAATAAAGGGTGAGTGTGGATGGGGCTATCACCC TTGGGTNGTGTTNGGGAGTTTAACATTTCTCTAGGTTTAAAACC 1 IMAGE:110582 T82892 3′ ATNCCTATNACCTTNCCACAANACCGGC ATAAGCCCTAGATATGATTTAATTTGAAGACTAGTTCATATTTT TACTTTTGANCCAATTCTAGTCTCATAAAATAAAAATTCAGGTC TCTCTGGGTCACACCACACATCTAAAAGTTGACAGTATGGTCTG GCACTACAGTCTCCTTCTAGGAGAAGTTTGGGAAATCATTCTAA CCCCTAGTTAGCTCCATGTATCTTAAGAATCACCAATTATTTGA AAGCTTGGAGGTTCTAGGAGGGGAGTGCAGCTACTCATATACCC 2 IMAGE:110582 T90074 5′ TTGACCGAGACTGGGCC TTCACAATCCAAATCTCAAATTACAGAAAAATGATATACCTTTC AGCTATGTTTTTTTGTGTGTGTGTTGGCTGGGAATGCCAAAAAG GTTGGCAAAAGGGGCAGGAAAAAAGTAGTGGGGCTCTCTGGTGT ACTCCACTCCTCACATGTCTACCATTCTGAGATTTTTGATGTCA GGTTCTGCCAAGTCTCAAAACCTCAAGAGTTGCCAGAATTCAGT CCCAGTGTACACATTCTACTCTAGGGAGAGGAAGGATAACAACC ACCCAAGGGCCACCCACCCGAGGACAGCCCTGCCTTTTAGGTAT GGGGGATGCGGGTGTTCATTCAATTTGCTTTGGGGTTTCCCTTC TTGAGGTCCCAGGAAAGGAGGATTTTCGGGGGAGTTCACTTTCT 3 IMAGE:121475 T97292 3′ TGCCCTTCAGGTCCCGGGGGGGAAGGCAACAGGGTTGAT ANGTCANANTNGGGTTATCAGGCATCAGTCTACCTGAGGAGGCA ACAGCATTGGTGGGTCCACCAGTAAAAAATGGACAGGAGACTGC TGTGCCCCCTTTGTGGGAAAAGCCTCCCTTGGGAAGCAGTGGTT GTATGCTCAGTCCTCCCCTGGGAAGAACAACAACAGGCAACTTG CAGGGTTCCCTTCAGAATGTCTCTCTGAGTGCACCTGGGCAATA AGCAGGCACAAGACCCTGGGGTGCTGAACCCTNTTCAACAGCCT GGGCAGGCAACGAGGACATTCAGGAANTACCAGCCAGGAAAGGC AGGAACCGTTTTGTTTGGGGTTCNTTTCCCACAACCGCCNTGTT TTTTCCCGGCAACAGTTGATTTTNAGGAAGGCAAAAGAAGGAAA 4 IMAGE:121475 T97406 5′ NTTTTCAGGG TAACTGGGAATTGAGAACNTGCAGTTCACACTCAACAGTACCAG GGCAGAAATGAACTAATGCATGCAATTTATTTAGCCTATCATGT GGGCTGTGAGTTTTTCCTGGAACATCCGGGCTGGTTTTCTTCTC TTGGNATAATGGTTTATTACATGTGAATCATATCATAACATAAA CTTGTTAGTTCCTGATTCCCGATAAAAAAGACATTTTATTGAAC AAATGAACAGTTCAAGGTCTAAGGCAATGATTAACCGAGCCAGT 5 IMAGE:121977 T97780 3′ ATTAAATGCTCTAGNCCTATAAGGGGAATATCCCATA AGGCAGGAACATGGGTTATTTATGAAGGATGCCTGTAGAGTTCA ACAAGCCTGCTTACTGCGGGTTAGTTGTGACCATTGTCTAAGGT AATTTAATGGTTTTCCTATGGAGGAGCTGAAGGGAGCCNTGAAA GGGGAAAAGGGTGGCTCCCAATGAGTTGGCAGCCAATGGGGAAC AATTTGGATATAATAAATAGGTCTCATGTTGACTCCTTTCCAAA ACGGCCTTTCAAAGGGGNAGTGTNGGCTTGGCCTGGCAAACTTC TCCCCACCCACTNCACCACA 6 IMAGE:121977 T97887 5′ GAATTTTTATTTTAAAACAAAGAATCAAACAAACAATAATGGAA AATCCATATGGAAATATTCACAATCTTCTCAGTGAGAAATAGGA AAACAACTTCCCTGCCTTACTGCCAAACTGAGGAGCCAGAAGTT GACGTGAAGTTGGAAGGCCACCTTTCCAGCTAAACCCCACTCCA TAGCTACGTGCATTTTTATTCAAAGGCTCCAGGGGGCAGAGGGA ACAGTGAGGACTNAGGACCCAAAATACTTGTCACTGGGCAAGGG 7 IMAGE:121981 T97782 3′ TTTTGGCTTAAAGGGGTCTTGAGG GAATGTTTATAGCCCAAACTTGGAATTTGTAACCTCAGCTCTGG GAGAGGATTTTTTTTTGAGCGATTATTATCTAAAGTGTGTTGTT GCTTTAGGCTCACGGCANGCTTGNTAATGTCTGTTACCATGTCA CTGTGGTCCTATGCCGAATGCCCTCAGGGGACTTGAATCTTTCC AATAAACCNGGTTTNGACAGTATGNGTCAATGTGCNGTGCAGCC CACACTTNTAGANGGATGAATGTATGTGCACTGTCACTTTGGCT CTGGGGTGGGAGTATGTTTATTGTTTGACTTATTTTCTCTGTGT 8 IMAGE:121981 T97889 5′ TTGTTCC TTCTTGATAGCATCACATTTTATTACTAATTGCAGTTTTTGATT CCACAACCCTGTATAACTTGGCATTCTGGTGAATTGGACCCGAA CATCTGTGAATCTTAAAAATAGTGGTTGACTCATTATGGCTTCC TTATGTATAGGATTAAGAACACAGATCCTGGGAATCAGACAGCC TGGCTTCCACACTCTAGCTGGGTGACCATGACCATGAAGAAGTT CCTGAATGTTCCAGTGTCAGTTTATTCACCTTTACAGAGAAATC TGGCCAAACACTACCCTCAGCCAGGGTGATCCAAGTTCAATATT CAGCAATTAAGGTCATGTTGTTTGTTAGGTGTGTGCTCTTGATA TGGCATGATGAGGAATTGCACTTCACTTCTGTGATATTCCCCCN 9 IMAGE:122702 T98928 3′ GGGCTTTTAACTTCAGGTCCCTGNAA NATTTCGGCACAGAGCGCTTCCATTGCTGACCTCTACCGACCTC TACCTGTGGTCCTTCCTCTACTGCAGCAGAGACACTGTTTTCTT CCTTTGTTCTTCCAACCCCATGGCACAGANACACTCTCCACTGC GGCCAAGGATTGCAGGAGAGGTGGCATCAGTGATTCAAGACTGC TTTTCCTACCTCTTCAGTGTTTCTTTCAGTGATCTGAAGTTAAA GCCAGGGGGAATATCACAGAAGTGAAGTGCAATTCTCATCATGT CATATCAAGAGCACACACTAACAAACAACATGACTTATTGCTGG AATATTGGAACTTGGATCACTGGGGTTTGGGTAGTNTTTTGCCA 10 IMAGE:122702 T98972 5′ GNTTTCTCTTGTNAAGGGTGGATTA GCTTCTTCTGGGCACATTGTTCTGACATAAAGGTTGCCTCCTTG TGGGGGAGAAGGGGAGGATTAGTTTGTTGGCTTGGGCATTTGAT CATAAATTATGGAGGTGCTGGACCGGAGAACCACCCACCAGCCC ACGGAGGCTACCGGGCATTCAGGATAAGGGCCGCCTTCTTCTTC AGAATAACCATACCCACTCCCTCTGAAACAAAGTGGAGAGTCTT AGGTCTGAGTGGAAACTCTAAATCTTTTAATTCTTGGGTTCAAC TTTCTTCATCTGTTTTCCTGGGTTCAGACTAAAACCATCTAACT 11 IMAGE:122723 T98941 3′ CAGCTGGGAGAAGTTATAACCGCTTTGTTGTTGGGC TACCCCGACAGTCTTCACACACACAAAAAAAAAAAAAAAAAGAA AGACAGACCAAGCAGAATNAAATAAAAGGTCTGAAGAACAAGTT TTGTTAATTTGCCACAACAGACTGTACTCCAGGGGAAGCTTTGT TGTCCATTAAAGTGAGTTCTCTGGGAAGACGAGTAGTAACCGAC TTGCACGATTTTCCTGCCTTTTCTATATTCTCTACTTACTATGA CAATACAGCACTAGGNATTTCCAAGTGCTTATTACCCGGCATAG 12 IMAGE:122723 T98991 5′ GTGCATGTATTTTAATGAGGG TTGGNTNNGAAGAAATAAAACTGCCTTTATTTGCAGATAACAAT CACATACATAGAAAATCCTAAGGGATTTACAAAAAAAGCTGCTA AAACTAATAAGGAGATTTAACAGTATTGCAGGACACAAAGCATT TCTGTATCCTAACAAAGANTAATTAAAAACTGGANTTTAAAAAA TTATTTAGGCTGGGCATGGTGGCTCACACCTATAATCCCAGCAC TTTGGGAGGGTAGCTGGATTAAAGGCCACACTGCCACACCCATC TAATTTTTGTATTTTTAGTAGAGACGGGGTTTCACCATGTTGGG CTAGGCTGGTCTCAAACTCCTGGGCCTCCGACCTCAGCCTCCCA AAGTGCTGGGGATTACAGGTTTGAGGCC 13 IMAGE:123735 R01179 3′ GCTTTTGCACATCAATAGGTATCCCTAGGAGGGCCTGATTCAGA AGCCCTCATTTTTAAACTCAATTCTTAGATGAACAGTCTTATTC ATCTGGAATGTTCCACATAATGGTCATCATAATTCTAATTTATC TTTAGTAAGATTTCACCATTTTTGTAAGTATTTGCAGCTTCTAG GCCCTAACACATGTAAAAGGTAAACATAGCCAGGAAGGTGAAAT ACACAGTTCTTTAAAAATTTAAGGGATGCTGGCCAGGGCGAGGT GGCTTCACACCTGTTAATCCCAGGCACTTTGGGGAGGGCTGAGG GTCGGGAGGGCCAGGGGAGTTTTGAGGACCCAGGCCTTAGGCCC AACATGGGGTGGAAACCCCCGTTCTTCTACNTTAAAATTTACCA AAATTTAGGTTGGGGTTTTGGGCCGTTTTGGGCCCTTTTATTCC 14 IMAGE:123735 R01291 5′ CNGTTACCCTTNT ACGGTAGTGGGTAGCGGGTCTCGGGTTGCGGGTTGCAGGTTGCA AGCCNAGCCCGCAGGCAACTNCCTTCCCGGCGCCATGTTCGGCT CCAGTCGTGGAGGCGTGCGCGGCGGGCAGGACCAGTTCAACTNG GAGGACGTGAAGACTGACAAGCAGCGGGAGAACTACCTGGGCAA CTCGCTGATGGTGCCAGTAGCNCTTGGCAGAAGGGCCGCGANCT 15 IMAGE:126450 R06699 3′ C TTTTAACCCGGTCAAGTCCAAAGGTTTATTTTAAGGCACAAGGT GGGNGGNCAAGGGGGATGGTAAAAGCGCAAGGGGTCGTGGCCTC ATCAAGGTCCGAAGGTCCAAGGGAAGGCGGGTCCGGTCCTGTTG GTCCTGGTCCCGAATTGGTAGCTGGGTGTATCTCCGGACCATGT TGGGGGCGCACCATCCCTTCCTCACTGGGACCTCCTGGGCTGGT CCANGCCCTTCTCCTCGGGGTCGCCTCCTTCCCGCTTGCAAGAC CTCCCGCGAAGTCCTCCTTGCTCAANGCCCGTGGGTTGCTTCTT 16 IMAGE:126450 R06700 5′ CANGTTCTTGTAGCCAAGGGGGCCAANAAGCGCT CTTTCTTATCTTTCAGTCCCCCATATGCCCTCCTCCAATAGAAT GTTTGAAATTACAAAAGGTTCAGACAACACCATAGAAGGAAAGA AATTACAAATGGNACACTATTTTGTGTATATTTGTTTTTAAAAA TTTCTGAATCTGCATTTAATGAATTTTTATTGAATGATGTGTTG AATATTTGTTACCNATAATTATTGAAATTATTGATAATTAATGA 17 IMAGE:127710 R09498 3′ TAATTA TGTCATAGACCAATGCGAAGTTTTTGGCCATTAAATATTTTTCT CTGTTCTAAATGCAGAGTCTTAGAAGCAAGACGTACTTTTCAAT TCATATCTTTCTACATTATATGAATTATATTTCACAATAAACAT ATTTATTTCTTTAGAGATGGAGTTCCGCTCTTGTTGCCCAGGGC TGAAGTGCAATGGTACAATCTCAGCTCACCTCAACCCCCACCTC CCAGGGTTCAAGGCGATTCTTCTGCCTCAGCTTACCCAGGCAGC TGGGGATTACACCCGTGCGTTCACCATGCCCGGGCTTAATTTTG TATTTTTAGTAGAGGACGGGGGTTTCTCCCTGTTGGGTCAGGGC 18 IMAGE:127710 R09603 5′ TGGG AAAGGANCCTTTATTGACCAGAGCAGGACCGTGGCATTTTTATA TATATATATATATATATAAAAGTNTGAAGACCTGGCAGGCAGTG ATCCNATTGTCCGCCCACCACCCCCAGCACTGATTTCCTGCTCC CTGCACGGGGAAGGGGGAGGATGACTNCTCCACCCAGGCCACAG GGCACACTCCCCTGCAAACAGAGGAAGAAAGGGGCTTTTCTGTA GCCACCCCCTGCACATCAGANATCAACAAGTATTCTCTCAAANN AANNNNNNTACAGNNTTTGANNCATTTNNNTNTGNNANNCCNNN GGGNNGTGAGTGGGGNNGNGGCNNGNGNGGNNNGGNCTGGGNGT TTCTTGGGGNNGGGNCTCCCNTGTCTCCCTTCCCNTTTATGGGG 19 IMAGE:128506 R10154 3′ NTTGGGGGTCTG GGTTATGATGGGGTGAAAAGGTGGACCAAAAACGTGGACATCTT CAATAAGGAGCTACTGCTAATCCCCATCCACCTGGAGGTGCATT GGTCCCTCATCTCTGTTGATGTGAGGCGACGCACCATCACCTAT TTTGACTCGCAGCGTACCCTAAACCGCCGCTGCCCTAAGCATAT TGCCAAGTATCTACAGGCAGAGGCGGTAAAGAAAGACCGACTGG ATTTCCACCAGGGGCTGGGAAAGGTTACTTCAAAATGTACTGCA AGCATCTGGCCCTGTCTTCAGCCATTTCAGCTTTCACCCAGCAG GGACATTGCCCAAATTTCGTTCGGGCAGATCTTACAAGGGAGNT GTTTTCACTTGCAAATTCATTGTTGTTNGGCCTNGTTACCCCAG 20 IMAGE:128506 R10564 5′ GACCCC TAAACATAANNNNTACAAAGTATAGTCTTCGTATTCACTACACA CCGCAAAGTTCTGCTACTTGAAATAAAGCAAATGAAGAAAATTA CGTTTTCTGACATAAAAATAATTATTATATCCACTGGCAACAAT AAGGAAAACTTAGCACTTATATATTTTATGATCAAATTGATTCA AAAATTAAATTGGTTAGCTTCAGCATCTATTCTGTCTATATCTC CCTGTGGGATGACAATTTAGACAATATGAACATTCTCAGGATAA GGAAATCTTGTTTTAAAATGTCCCAGGCATCCCTTCCNCTGGTT AAAACTCCCTATATTTGCCTTATTATAAAATTCAGGGCTTTCTT 21 IMAGE:130742 R22024 3′ CCNCCAGGTGGGCCCAATGGCCCAAGGGAC CAAACATCCAAACCATTTCAGAACTCATTCTATAAAATATATAA ACAGCTTTCTATTTTTTTTCTAGCTGCATAATATTCCATTGTGT GGATGAGCCATAATTTATCAATTTCCTATTATTTCTAATCTTTT ACAATAGATAGTGTTTCAGTCCTTAATCTTATACATATAGGTG GCCATAAATTTTTAAGGTTCTTTGGGCTATTTGGCCAACATGT GGGAAGGAAAGCCTTGGAATTTTATAATAAGGCAAATATAGGG 22 IMAGE:130742 R22077 5′ NGTTTTAACAGTGGGGAGGGATGCTG GAACAGTTCAATCCTGGGCTGCGAAATTTAATAAACCTGGGGA AAAATTATGAGAAAGCTGTAAACGCTATGATCCTGGCAGGAAA AGCCTACTACGATGGAGTGGCCAAGATCGGTGAGATTGCCACT GGGTCCCCCGTGTCAACTTGAACTGGGACATGTCCTCATAGAG ATTTCAAGTACCCACAAGAAACTTCAACGAGAGTCTTTGATGG AAAATTTTTAAAAAATTCCACAAAGAGATTATCCATTGAGCTT GGAGGAGGAAGGATAGGACTTTGACGTTGAAATTTTATTGAAC GGCACTTCTTTAAAAAGGTTACCCAAACCAGGNCCACAGGATT 23 IMAGE:131318 R22950 3′ NATTTGGNTTTTTTTGGGG GATCAAGTTAGGAAACACACGATTGAAATCTGGAAGAGAAAAC TGGCTCCTACCACATTGCTTCTCTCGATCATGGGTGAAGCCTG AGGAGTTCCAGACACGGGGGTAGAGGCTGGGGTCTTTATTTCT TCGATCATATTCATGATTTTCTCTGGGCACTTTGATGGCATCA ACACAGGTCTCCTGCCACCGAGGCAGCTTGGGAATTCAGTAGT TCTGCAGACTGTAAGTGATAATAATGTATGTGGGTTTTGCAAA GCCACAGTGCTTATTCAACCCAGGAAAGCAGGAAGCGCCTCTT TCTCTTTCAAGCAGGAGCCTCNTTTGGCAACCCNTCTTGGCAA TGGANTTTCTGGGGATTTTCACTTCTGGACGGAGGAAGTTAAC CGGGTTNTTCCCACCATACTTCCAATTTCCTTTTGGTGGTTTC CAAATTTTGGAGTGGCGTTTTCGGGCCTTCCCTTGGGGNTTTT 24 IMAGE:131318 R23056 5′ CCCNTCCTGAACCTTTT TACACATGTGTATGCATGAAAAATTTCTAGAGGGTCATATTAA TGTAAGAAATTGTGAAGGGTGGTCTCTAGGGCATGGAGCTTAG CAGCTAGTGATAAAGAAACTCACTTGTCATTACACTTACTGTT TGAATTTACAATGTCATGTTTCATTTTCATAATTTAAAAAAGT CAGTGCCAAAACACTTACATAACTACTTACATTTCTTATGTAT GATTTGACTGCTTATTTTAAAGTTTACTGTATTTAAAGTTCAA CATCAAAAGAAAGGGCTAGGAAAAGTGGGTGGGCTAGGACCTA GGTTCTTTCACACTACTTCATTTCTAGGCTTCCACATGGCTCT 25 IMAGE:133613 R27606 3′ GGTAATAGCCAAGGC AGTTTCTGTGTTCAAGTTTGAATACTCTTGAAGTCTTATTTTT TTCATTTTCAGATTTTAAAATTTTCAAAGAAAAGGCGTTGCTG ATGTCTGAAATCTCAGATGCCTGAAATTCAATTGACAATTACT GAACAACAGTCTCTTATTTACATAAAGGTGGGGTTGTCAATCT TGGGCTCTCAGGAATTTTCTCTTGTAGGGCACTGTGTAGGCTA AAGGTTATTTAAGGTGATTTCAGAGGTAGGATAGGATTACTCA GTGGATTACTACCCTGTTGCCAAGGTTAATTCCGGNAGGGGTA 26 IMAGE:133613 R30836 5′ ACCCCCGTTNCCAGTTCACGTTAGNGT AGAACAGGTACTTCGTACTGGGATTTCGAGGCTGGCATCCTGC AGTATTTTGTGAATGAGCAAAGCAAACACCAGAAGCCTCGAGG AGTCCTGTCTTTATCTGGAGCCATAGTGTCCCTGAGCGATGAA GCTCCCCACATGCTGGTGGGTGTACTCTGCTAATGGGAGAGAT GTTTAAACTGAGAGCTGCTGATGCAAAAGAGAAACAATTCTGG GGTGACTCAGCTTCGAGCTTGTGCCAAATACCACATGGGAAAT GGAATTCTTAAGGAGTGCTCCCAAGCTCCCCGAAGCCGAAGTC TTCACTTTTGCTTCCCACATGGGAACACCCATTCTTGCGTCTT 27 IMAGE:135608 R32892 3′ CCCTGTTAGGCCAGAGACACCTNAA GCCTCCATAGAAAGGCTTCGTGTGGAATATCACTGTCGCTGAG TACCCAGTCTTGGCACAGTTGATGCTGACTTTTCCTCCGAGCT CCACCCACGGGATGGTGAGAATGGACCGGGCGTAGGCACTAGG CAGGGTGAATACGTACTCCTCCCCGTGTTCCAGGAGCCTCAAC ACACCTTCCCCTATCATAGAGACCCCCACGGACATGCCCATGA ACTTGCTTTTGGTCCATACATGAGTGTTGACGCACAGTCTCTT CTCCTCGCACTCACAGTAGAAGCAGGAGATGGGTGGGTGATGG GACACTTGCTCAGCCACAAACCTTAGTTTGTAGCTTTTGGGAA GGGTCATCGGCCATTTGGGTNTTCATGACAGCTGGCAGGAGAG 28 IMAGE:135608 R31395 5′ CCGGGAAGCAGTTCTCTTTAGGT GCCGCATGGGAGGCATGGCCCCGGGGTCCTGGTGGCCACTCGT GCCTGGTGGAGAGCGAGGGCAGCCTGACGGAGAACATCTGGGC CTTCGCTGGCATCTCCAGGCCCTGTGCCCTGGCCCTGTTGCGG AGAGACGTGCTGGGGGCCTTCCTGCTGTGGCCTGAGCTGGGTG CTAGCGGCCAGTGGTGTCTGTCCGTGCGCACGAGNGCGNTNNG TTGCCCCACCAGGTCTTCCGGAACCACCTGGGGCCGCTACTGC 29 IMAGE:136909 R36650 3′ TTGGAGCACCTGCCGGCAGAGTTCCCCAGCCTGGGANGCTTCT GTCGAGTTAGGAAGGGCCCTGGTCACCCCTCTAAGCCTGCAGC TCACTGCTGGCCCCTCCCTGTCAAATGGCTAAAGGAGATGAGC TGGGGGTGGGGGTGCCCTGGTGATTCCTAGGGGGAAGGGGTGA GCCTGCGCATCCCTTCTGAGAAAGCGGGAGTCACAGCCCTGAG GTTTTGAGTGGAGACAGCATGGAGATTCTTGGCCCTGTCTGCT GGTGCGCATCCCTTTCTGCACACAGGAGTCCACCGTGCGTGAN GTTTAGGTACAGCCCTCTGTCCCTCCTTGCCCTCTCTTGCACC TTCCCACCCCTCCTTTCACTTTTCAGATNACATATTGAGGAAA CAGCCCTNGTTCTGTTCAGCNTAGATGGGGGTTCATCCCCAGC 30 IMAGE:136909 R39730 5′ CT GAGTTTAATGATTACATGGNGCTGAGTCAGGAGGTAGGAGGAG ATTCTTAAATCTCTGAAGAGTTCTGGGCTGGGGTTCTGGGAGG CAAGGGGCTGGAAAATTTGGGCCACTGATTGGTCAGGGTAAGG GAGATTGAATCATTAGGATATGGAAATTGCATTCTTTGATGAT TTAGCTTCTGGTAGGGNCCTTCAGACCAGGCTGACATCAGTAG TTTCATCAGTATGCAGGGNCAACCAATCATGGCCAAGTCCNCT 31 IMAGE:136919 R36539 3′ TTNAGGGANTTTGTNCCCGTAGGATTTATCCG GCTGATCGAACAGCCTCACTTGTGTTGCTGTCAGTGCCAGTAG GGAGGCAGGAATGCAGCAGAGAGGACTCGCCATCGTGGCCTTG GCTGTCTGTGCGGCCCTACATGCCTCAGAAGCCATACTTCCCA TTGCCTCCAGCTGTTGCACGGAGGTTTCACATCATATTTCCAG AAGGCTCCTGGGAAAGAGTGAATATGTGTCGCATCCAGAGAGC TGATGGGGATTGTGACTTGGGCTGCTGTCATCCTTCATGTTCA AGCGCAGGAAGGAATCTGTGTTCAGCCCGCACAACCATANTGT TTAAGGCAGTGGGATGGAAAGTGGCAAGCTTGCCCAAGGAAAA NGGGTTAAAGGGAANTTTTTTGCCACAGGGAAGGAAACACCNT 32 IMAGE:136919 R38459 5′ GGGCAAGAGGGNACCATTTACCAGGGGGCA ACCAGAAAATAAGACATTTTATTTTGAGAAATAAATTGGAAAA AAATATTTTAAAATGTTTAATTTGCAATATACATAATACTGGA ATTGAAATGCTGTCTGATGGAAATGTTGCAATGTGGAGTAGGA GGGTCAAGTTCGTGAAGATATTCTTAAAATTAATCTTGGAAAC TCTGTGCCTATGAGGTTTCTCTAAAGTGGCTAAAATATGCATT TAATATGTTGTCTAAATGAGTACATTTAATTCTAGAGACTGTA AGGAGTAGGAGATTATATGCTTTGGGGGCTTTTGTAGGCNTTT 33 IMAGE:138496 R68635 3′ TTTTTAAAATCAGTTGT TAAATGCATTATTCATATTTCTTGAAGCTTAGATACAGTCTAA TTCATAGCAACCATATCTGCTTTATCCTAGGTGAGGGTAGCAG TCCACAATGGAATAGAAGAAAATCCCATTATAACAAATGACAA ATTATATATCATGAATCCTTCTGTCTGACTAACTCAATAACTT TCTATAAAAGCCAATGGAATTCAAATAGGAGCTAGGAGACAAC AAGTTATATATGACAGTGGAGGTTGTATTCCTTTTATATTGCT GAGAAAACTAGTTAAATGATCAGATTCTTGGCTGTTAAGGAAA CAATTTTCGTTTAATGGGGATCTGTACAACTGATTTTAAAAAA 34 IMAGE:138496 R68634 5′ ATGGCTACAAAAAGGCCCCAAAGG TTTTTTATCCTTCTTAANNNTTATTACATGTTTTATTATCCTG TCCCCAGAGGTGGGTTTATCCAGAAACCAAGAAAAAAAATCAA TCAGAATAAACTCAAAAAAAAAAGGTAGGGGGAGCAAAACCAT CAACCACCAGGGCAGCCAGGCCATCAGCCCACCTCCACCTCTG GAGGGTCCCCAGAGACCCACGCCCGACGCAGACCCGGAGGAGG CATCAGCAAGGGGGCCCGGGCAGAGAATCGGCTATGTCTTTCA TTATGAGGAGGCAGGGAGAGACGGGCAGAGATATGTTTGCTAG GGTGANTATATATTTTATATTAATTAAATCCGTAAGTTTAATT AAAGTAAATAGGTATTTCTCTGGAAGTTTTTTTAATTTCTTTC NTTTTTTATAGTTTTTTTGGTTTTTTGTGGNTTTTTTTTTTTT 35 IMAGE:140951 R66605 3′ TTTTGGGGTTT CAAGCACCCCGCTTTTGCAGCAGAGGAGCTGAGTTGGCAGACC GGGCCCCCCTGAACCGCACCCCATCCCACCAGCCCCGGCCTTG 36 IMAGE:140951 R66604 5′ CTTTGTCTGGCCTCACGTGTCTCAGATTTTCTAAGAACCA GGAATCTACTNCGAGCACAGCAGGTCAGCAACAAGTTTATTTT GCAGCTAGCAAGGTAACAGGGTAGGGCATGGTTACATNTTTAG GTCAACTTCCTTTGTCGTGGTTGATTGGTTTGTCTTTATGGGG GGGGGTGGGGTAGGGGAAAGCGACAGGAAGTAACATGGAGTGG GTNCAGCCTCCCTNTAGAACCTGGTTACGAGAGCTTGGGGCAN TTCACCTGGTCTTTGACCNTCATTTTCTTNACATCAATNTTAT TAGAAGTCAGGATATTTTTTAGAGAGTCCACTNTTTCTGGAGG GAGATTAGGGTTTCTTGCCAAGNTCCAAGCAAAATCCACGTGA AAAAGTTGGNTGATGCAGGTACAGGNTTACACGNGGGCATAGT 37 IMAGE:159608 H15842 3′ TTNCCATAGTCNGTTGCCAGGG CCAGTCACCAAGACAGGCATCTCAAATCGGCTGATTCTGCATC TGGAAACTGCCTTCATCTTGAAAGAAAAGCTCCAGGTCCCTTC TCCAGCCACCCAGCCCCAAGATGGTGATGCTGCTGCTGCTGCT TTCCGCACTGGCTGGCCTCTTCGGTGCGGCAGAGGGACAAGCA TTTCATCTTGGGAAGTGCCCCAATCCTCCGGTGCAGGAGAATT TTGACGTGAATAAGTATCTCGGAAGATGGTACGAAATTGAGAA GATCCCAACAACCTTTGAGAATGGACGCTGCATCCAGGGCCAA CTTACTTCACTTAATGGGAAAACGGAAAGATTCAAAGTGTTAA AACCAGGGAGTTTGAGGAGCTTGATGGGAACTGTTGAATTCAA 38 IMAGE:159608 H16152 5′ ATCGAAGGGTTGAAGCCACCCCCAN NTCCACGATCTGCTCANNCNGNGACCACGCCCTTGGCAGTTCG CCCTCGTAGTAGATGTCTACCACCTCGGCCGTGAACGTCCTGA TGGCTTCCCACACCAGGAGCCCGTCGTCCCGGTAGAAGTAGTA GGGGATGTCTTCTTTGCTCTCCATGCCCCGGGCCTTGATGGCC TCGGGAAAGCACAGGGAGGCATAGGTCAGGTCCTTCATGGCCC TCTGCACCATCTGCACGTGCCCACCGCCCCCTGTGGCGTTGGC CTTGTCAAAGAGGCCACACTCGCAGATGAGCTGCTCACGGGCC TTGGGTGTTGATTGCAATGGTAAATCTCACGTGTGCCACCAGC AGCTTTGAAAATGGGGGTGCACAGCAGGGCAGCTNGGCGGTAA 39 IMAGE:179890 H51574 3′ CATTTGC CTGGGCGAGATCCAGCTGGTCAGAATCGAGAAGCGCAAGTACT GGCTGAATGACGACTGGTACCTGAAGTACATCACGCTGAAGAC GCCCCACGGGACTACATCGAGTTCCCCTGCTACCGCTGGATCA CCGGCGATGTCGAGGTTGTCCTGAGGGATGGACGCGCAAAGTT NGCCCGAGATGACCAAATTCACATTCTCAAGCAACACCGACGT AAAGAACTGGAAACACGGCAAAAACAATATCGATGGATGGAGT GGAACCCTGGCTTCCCCTTGAGCATCGATGCCAAATGCCACAA GGATTTACCCCGTGATATCCAGTTTGATAGTTGAAAAAGGAGT 40 IMAGE:179890 H50910 5′ TGGACTTTGTTCTNAATTACTCCAAAG TTATTTAAAACTTAATTCTCACCTTGAGTATGCAAAATACAAA CTCCACAAAATGTTCATTTTACTTTGTAGTTTACAAATATACA AAATAGACGTTTGCTTAAATTTATATTACATATTTATTAAGGC AAGGAACTATATAGAAAAACACATTTGTTCTGCTTAAGGCATA CTTGGGAATAAACCATTGTACAAATTATTGCACATCTGAAACC ACAGTGCATAACAGACTGTCTGCATAAAAATGCTAAAGANGTA AACCAGGGTATATTACCTGACTTAGGGTCATAAATGTTGATCG GAGGACAAATATAGGATTTTCCTTGTCAAAGTATGCAGGCAGT TTGAAAACTTTGGGCTTCCNTGTTTGGGNACCTTTAGGANCCA 41 IMAGE:188232 H45668 3′ AGGTCTCACCAAG CTGGACTTACAAAATGCCAAGGGGGTGACTGGAAGTTGTGGAT ATCAGGGTATAAATTATATCCGTGAGTTGGGGGAGGGAAGACC AGAATTCCCTTGAATTGTGTATTGATGCAATATAAGCATAAAA GATCACCTTGTATTCTCTTTACCTTCTAAAAGCCATTATTATG ATGTTAGAAGAAGAGGAAGAAATTCAGGTACAGAAAACATGT TTAAATAGCCTAAATGATGGTGCTTGGTGAGTCTTGGTTCTA AAGGTACCAAACAAGGAAGCCAAAGTTTTCAAACTGCTGCAT ACTTTGACAAGGAAAATCTATATTTGTCTTCCGATCCAACAT TTATGACCTAAGTCAGGTAATATACCGGGGTTTANTTCTTTA GGCNTTTTTATGGCAGACAGTCTGTTATGGCACGTGGGTTTC AGATGTGGCATTATTTGTACATGGGGTTTNTTCCCAGNATGG 42 IMAGE:188232 H45711 5′ CCTAT TGCACATTCTGTTTTTACCTCTGTCACTGACTCTGTGGGTCT AGCCATGTCATTTAACCACACTTGAATTTCAGGTATTTTGTC TGTAAAATGAGGATAATAACGCCTGTCTACTACATTAAACCA CAAGATGGTTTAAAGGTTAGCATAATAAATTATTAGAGTATG ACCTAGGAGTTACCTAATCTGACCTCTTTATTTTACAGATAG AAGTACAGAAAGGTAAATTGAATTGCTCAAGGTCACCCAGTG TGTGGCAAAATCAGAACTGGAAACTTAGGTCTTCTGCCAGTC CCATTCAAGGGCTTTTTCCATTGTACAGTTAAATTATATGTT GTGTGTAAGGCATAGTATAAACTGTAAACCATTCATGCCAAA 43 IMAGE:193771 H47895 3′ TGTTCAGGTGGATTGTTTTTCCCTCAGTTTT CTCCTTCTCTTCTTGTTATTATTATCATTATTATTATTTTGA GATTGATTACTTTCCCATAAAAGTGGAATATACTTTGCTTTG GTTGAGTAATGCTCTAATTATCTGAGGTCTTACAGTAATTGA TTCAGACTGATGACCACCTGCTGCCCATTCCACATGGGCAGG GACACAGCAATAATGAGAATTAGGGTTAGGCTCATAGGGGAT GGAAGCCAGCAGGGAAGGGACTAAAGCTTTGGGAGAAAGCTG AAGGGTGACTACTGCCCGGGGGCTTGAACTTTCTAATGGGCC ATGGCCTTNCTCTGAAAATGTAATTACTATGACCACTGGGTT AGGTGATGTATTTTTCATTTCTTACCCACTCTCCATCCCTTT 44 IMAGE:193771 H47896 5′ TAAACACTGCA GGCCCAGATCCTCTGGACTCCTCAGATGAGCGGATTCAGAGA GAAGCTTTTCAGAGCGTGCTGGCGGAGACATTTTTCACAAAA GAGCCCTTGCGNTGCTGGTGTCCGTGGCGTGCCTGGGAAGNC CACCAACGCTGGCCGGCCTCCAAGCACCCGGGCCTCTGCTCA TGTACAGCTCCTGAACTGCCCTGCCTCTGAGTTACTGTGGAA AATGAGCTTATATATGAAGAAGTCAGCGAGTGGACAAAGCCA GGCGCAATGGATAGCAAAGATGTGGGAAGTCTCCTCGATTCA AGTTACAAGAAAACCGCAGCATGGAGTCTNCTCTCAGCTGTT TGGGGGNATTACCGATGNCTTTGACTAAGTCAAGACTGACTT TTTCCAGTAATTATCACCCAAGNGGTTAGGAGGNCGTTCCCT 45 IMAGE:201981 R99526 3′ GTTCCAAGTTTTTTGNCGTTAGCNTTTT GAAGGGCATTCTCAAAACGTNNCCGCACAAGCAGACCATCCC TTTTATTTTCCCCGTCTGTCTCCTTTCCTTCTGCTTTCAAAA TGTCTCAAGAGTATTTACAAGAGTTGAGCAACACAGGCATCT TTATCTGGGGTCTTTATCCACAGAGCAGAGGACAGGAAGTCA TCACTACAGAGACGAAGCGATGTATGGTTTGACCCAGTGGAG GACTTTGTTAAGGTGGAGGTNTGAGTNTGGAGTGTAAACGTG GGACATCCAGGGGCAGTGGAGGGTAACCACTGGGAGAGGAAG TCTGGGGGACAGTTTGGGGAGCCAGCCAAATNTAAAAATAAA GCATTTCTGTTCTAAATCCAAATGAACCTTTNTACGCTGCTG 46 IMAGE:201981 R99527 5′ TCATCTTCCAGTATACCCCAGGG CTAAGGAAGGGCCCATCCTCACTGCAGAATCAGAAACTGTCC TCCCCAGTGATTCCTGGAGTAGTGCTGAGTCTACTTCTGCTG ACACTGTCCTGCTGACATCCAAAGAGTCCAAAGTTTGGGATC TCCCATCAACATCCCACGTGTCAATGTGGAAAACGAGTGATT CTGTGTCTTCTCCTCAGCCTGGGAGCATCTGATACAGCAGTT CCTGATCAGAACAAAACAACAAAAACAGGACAGATGGATGGA ATACCCATGTCAATGAAGAATGAAATGCCCATCTCCCAACTT ACTGATGATCATCGCCCCCTCCTTGGGATTTGTGCTCTTTCG CATTGTTTGTGGGCGTTTCTCCTGAGGAGGGGAAANTCATGG GAAACCTATTTGTTTCGCAGAAACACACAAGGGTTAGGATTA CNTGGGAGATAGTTAAAATTGTTCCTCAATGACGTGGCAGGC 47 IMAGE:202315 H53024 3′ TTGGAGGGGGAGACGAAGACGGCCTT TGAAACAAGGAAATCTACTAAGACTTATTTTGACACTGGAGT GTCATGCCCCCATCCTCAATCTAACATGCTACTGCGTTGTTA GAGGGTAAAAAGGCCGTCTTCGTCTTCCCTTCCATGCTGCAC GTCATTGAGGACATTTTTACTATCTCCAATGTAGTCTAGCCT TGTGTGTTTCTGCGAACAATAGGTTTCCATGAGTTTCCCTCT CAGGAGAAACGCCACAAACAATGCGAAGAGCACAAATCCCAA GGAGGGGGCGATGATCATCAGTAGTTGGGGAGATGGGGCATT TCATTCTTCATTGACATGGGGNATTCCATCCATCTGGTCCNG 48 IMAGE:202315 H53025 5′ TTTTTTGTNGGTTTTGGTTCNGGATCCAGGGGACCGCC TACGTTTTGTATGTTTTTTTATTTGCTCCAGGTGGGGTTTTG ACTGTCACTTTCCCACACTCTGGATTAGTTCTGATCCCACCA CAAGGAGCCCTCGAATTGGCTAAAGTGAGAAACTGGGCCTGA AGACTCCGTACCCTCTGCCATCTTGCCGAGGGAGTCTCCTTT TAGAAAACAATCAAAGGGTTATTGCATGAGTCTGGATGAATC CCACTCTCAGCTGTCCACGGGCCCGACCACCTCATCTAGCCC CCTTTTTGGCAGGGAGAACCTGGGCTCCCAAGTTCTCCTCCT TCACTTCGTTACAAACCAAGGGGAAGAGCCCACCGTGAGAAC GCGNCATCTGCAAGCTGTCTCCCTTTTTNCATCCTTGGTNGA 49 IMAGE:202514 H53239 3′ AACCCTT TNTTTTGTTGNCTCTAGCCTGANCAGATAGGAGCACAAGCAG GGGACGGAAAGAGAGAGACACTCAGGCGGCACANTTCCCTCC CAGCCACTGAGCTGTCGTGCCAGCACCATTCCTGGTCACGCA AAACAGAACCCAGTTAGCAGCAGGGAGACGAGAACACCACAC AAGACATTTTTCTACAGTATTTCAGGTGCCTACCACACAGGA AACCTTGAAGAAANTCAGTTTCTAGGAAGCCGCTGTTACCTC TTGTTTACAGTTTATATATATATGATAGATATGAGATNTATA TATAAAAGGTACTGTTAACTACTGTACAACCCGACTTCATAA TGGGTGCTTTCAAACAGGCGAGGTGNGTAAAAACATCAGNTT CCACGTTNGCCTTTTGCGCAAAGGGTTTCACCAGGTTGGGGA 50 IMAGE:202514 H53133 5′ AAGGGNGACAGCTTTTT CATTAAATCAGAGTACTTAATGATACGGAAAAAATTCCTATT AAGTGAAAAAAGCATTACAAAACAGCATATATTATGAGCTCT ATTTTTATTTTTGAAATATATTTATGCAGAGAAATACAAAAT GTTAACAATATTATCTTAAAANAAAAAAATANGGCTGGGCAC AGTGGCTCACACCTGTAATCCCATACTTTTGGAGGCAAGGTG GGTGGATCGCTTTGAGCCCAGGGNGTTCAAGACCAGCCTGGG 51 IMAGE:203114 H54419 3′ GCAACATGGGCGNAACCCCGA TGTTCCTCCCCNNTCCCCCAGGGATAAGAACCTGTTATCCAC CATCAGTAACATTTTATGAAAGATCTACTTATTTGTCTGTTT TGCAGACATTTTAAAATTCATAAAGTGGGATGCTTCTTTAAT TTAAATACATTTAGCTTCATGAAAAACTCACTACACAGTTCT TGTTCAAGCATTATTGGGAAACCACCAGAGGGCACTCTCACC 52 IMAGE:203114 H54509 5′ CAGGGCTTAATTTGAACATCTCGCCCAAAAGTGACTTTTAA ATATCGGCACAGCACTCAGGAAAGCCTAAAGCTTGAAGACTC CATTTATTTATAGTGCATCCCAATCCAGATACGTAACAATTA ACGAGTTATTTTTACTATAAGCAAAGTTGCCTAAAATCATAG TTGATACTAACCATGGTTAACAGAGCTCTAAAGTTTGACAGA AAGTGAGATTCAAATCCTTTCACTCTCATATGCTAAACCTTT TGCCTTACTCTGGGTCATCAGAGAAATTTAGGTGAGAATGTA TGATGAAGTCTGTGTTTTAGATTCAATGCAGATATATCATTG TGGGCAGAACTCTTTCTGGTTATATCCAGTTAAGAGTAAATC AGGCTTTCAGCGNGTCGCGGTGGCTTCACGCCTGTAATNCCT AGGCACTTTNGGGAGGNCCGAGGCGGNGCAGGNTCCACGNAG GTTCAGGNAGATCGAGACCTTNCGGGNTAGCACGGGGGTTTT 53 IMAGE:204740 H57305 3′ NACCTTGTTGNTTCAGGCTGGTTNG TAAGGAAAAGNNTTAATAAGTAAATATATTTATTAAATATAA AAGGTACACAGTAAATATAAATGAACTAAATGCTTTAGTTAA AAGACAATAAAAATTATGAAATAAAAATGTATACACTTGAAA GTATTTAAAATAAATCTAATTTTCATAATGAATTTTAAGCAT 54 IMAGE:204740 H57306 5′ TAAGGAGTTTTGTAACTGANTAGTGGAACTC AAATGTTAGAGGGTGCGGGGGTGAGGACTGACCACAGATTCC CTGGATAGTGTAGTGGTAGATTTCTCCACAGGATAGCGCAAT TGGCAAATCATGCTTGGTTGTGTTAGGCCAAAATACTAGTTT TGCTTTCTTTACCTTTTCTATCTTGATGAAAATGTTGCACAT TCTATAGTTGCAAAACACATAAAAGGGGACTTAACATTTCAC GTTGTATCTTACTTGCAGTGAATGCAAGGGTTACTTTTCTCT GGGGACCTCCCCCATCACCCAGGTTCCTACTCTGGGCTCCCG ATTCCCATGGCTCCCAAACCATGCCGCATGGTTTTGGTTAAT GAAACCCAGTAGCTAACCCCACTGTGCTTNCACATGCCGGGC NTAAAATGGGTGATATNACAGGTCTTATTATCCCCTATTGGG ATTTATNCCTCAAACCNCTTAAAAACAAACAGTGGCCTTTTG 55 IMAGE:205049 H57493 3′ GCCCTTTG GATTAAGAACGTAAGCTCCTTTATTATTATTATTATTATTAT TANTCATNCCCTGTTATTTACCCCNAAACAACAGCATAACTC AAATAATAATGACACACACGTCCCGCCCATATACACAATACC ACTAGCCTATCTGTCAGGCTATCTGGCCTTTGCTTGGTTCCT GATGGAGCTGTCTGGAGACACTCNCCNCTGTAAAAATCCCGN CTTAAACACAGGGGACAGAAGAAAGGGGGGACCTAGGTCAGA TCATAAACTGACAGGCTCCCAGCGTCCTTAGGGAGTGCTAAT GTGGGAGACTTTGAGGACGTGCTTGGACACATTCTGGGGCAG ANGGCAGNAGGCACTGT 56 IMAGE:205049 H57494 5′ TTGTTTTTATGTGGNTGATGGGGTAAATTCC GTTCNNTTTTCCTTNCTCATTTNATTTTAAAGTTTTATTATG AAAACACATGGAATTAACGGTGTTATCCATGTATTTGCAACA GCAGAGAAAGAGTGAGAGTGGACCATCCCCATAGGANCNACT TATCCTTTGGCTAAACTAATATAAATAATGGAAATAACACCT AATACAATAATACAGCACATAAAAGAGATTACATTAAGAGAA GAGACAGGAACTGCGGAGAGGAGTCCTGAGTATGGAGGAGAT GCGGCTCATGGAGAAGCATCCAGGCTCAGGTGACCTTCCCTG AAGACTTCCTGTCTCTGAGCAGCTCAGTTCAGTTCCAGGGTC ATACACGTACTCCGGGACCCGGGNCTCACTGGGGGGTCAGCG CAGACTTGCTTGCCTCTTTTGGGTTTGGGAATACCACAGCTG 57 IMAGE:205633 H62864 3′ GGCTNGGGGAGCAGAGGNTGCTGGGTTTC CTGAGAGGAACTCCTCACTCAGCTAGCTTCAGGAGCCATGAC ATCATCTCTACCATGGAAATTCCACTCACTCTCCTGTGCCCC CACATTTGTCCTAGGCCTCAGAGTCCCTATAAAGAGAGATTC CCAACTCAGTATCAGCACAGGACACAGCTAGGTTCTGAAGCT TCTGAGTTCTGCAGCCTCACCTCTGAGAAAACCTCTTTGCCA CCAATACCATGAAGCTCTGCGTGACTGTCCTGTCTCTCCTCG TGCTAGTAGCTGCCTTCTGCTCTCTAGCACTCTCAGCACCAA TGGGCTCAGACCCTCCCACCGCCTGCTGCTTTTCTTACACCG 58 IMAGE:205633 H62985 5′ TGAGGAAGCTTCCTCGCAACTTTGTGGTAGATTANT AGCTCTGCTAAAAACTCCAGCGCAATTTGATGCTGATGAACT TCGTGCTGCCATGAAGGGCCTTGGAACTGATGAAGATACTCT AATTGAGATTTTGGCATCAAGAACTAACAAAGAAATCAGAGA CATTAACAGGGTCTACAGAGAGGAACTGAAGAGAGATCTGGC CAAAGACATAACCTCAGACACATCTGGAGATTTTCGGAACGC TTTGCTTTCTCTTGCTAAGGGTGACCGATCTGAGGACTTTGG NGTGAATGAAGACTTGGCTGATTCAGATGCCAGGGCCTTGTA TGAAGCAGGAGANAGGAGAAAGGGGACAGACGTAANCGTGTT CCAATACCATCCTTACCACCAGAAGCTATCCACAACTTCGCA 59 IMAGE:208718 H63077 3′ GAGT TCTTGTGACGTCATTTTATTTTCAGCTACATAGACATCTTTC TCATGTATTGTTACTAGAACAACTTGTATAGGGTTTTATGGT TTGGGGAAAACATTTTTAAAAAATGGACTTATCTCTATTATA CAGAGTTATAATATAAAAATGATTTAAAGGCTATATTTTTCA GCATGTAGGTAGCTACACTGTAATCCTGTTGAAGANACTTTC CTATTTAAGCTTATAGGATGANAATATATAATTAAAGTCTTC TGATCATAGCTTGAGACCATCAAGGGANTGTTTAGTTTCCTC CACAAAGAGCCACCAGGGTTTTTCTCATAATCTCCTTTGGGT 60 IMAGE:208718 H63161 5′ TTCATCCAGGGATGGCTTNGCAAAGGGGAGTTACCAT AATTAAAGCAAATAGACTGTTGTAGGTACCAATTCTCAATGT CACAGTGTTACATGGAAAGTAAAATACACAAGAACAGCCCAA AAGATGGAAACAATGGACGTGGTCAAATGACATCAGTACAAC ATCCATATGGTCCTAAGTAGCCATCTTTAAAATGGGTTAGGA AATGCCTTCAATCATTCACACAGGACACATGCATTGGAACAA ACTCTAAGGAAGTGTTCTTACACGGGGAAAAGGCAAGTTACA GGATGCATGGGGCATGGATATGGGGTGTAGGATGTGTGGTAT GGTGGCATCCCCACTTCATACACAAAATACCCCGGCATCGGC 61 IMAGE:210368 H65343 3′ CCACATGGCCTGCTGTGTGCGGTAGG TAAAAAATGATCGTTATGTAGGTGATTGAGAAGTAAATGTAT TCTTTTTTAAGGTAAAAATTTGGACCCTTATCATGCATACCC CCCTCTGTGCTCTTCAAATCAACATCATTATTAATATCTGTA CATTTTTGCTCATCTGAGCCAGCACAGGCTGAGGCTGTCAGA ATGGACACCTTTTGGTTGTTGGGTTTCTGTCAGTTTCTGGGG TGAAGCTGCGTGATTGAGAACGTAGCTCTTGGGCTGCCATCT CGGGGATTATTAAGGACTGTGAACTCTATCCACAAGCCATGG CAATATCTGTCCCACCGAATGCTNCCTCTAAACACACTCTTA 62 IMAGE:210368 H65547 5′ CTTCCCGTGGATGTGTTGTTAAGGGGTNCCGATTGANGGCTG ATGGGTCATATTTTTGTTCACTGAAAGGACCAACCAGTTTCA TCAAACAAGCTTTAGAGAAAGAGAAACTGAGTAATTCATCTT GTCAGTTACAGTTCACATATATGCACACACATACAAACTGGC TCAGCATCAGTGAAACATAACTATTCAAATACAAAAGTATAA NAAACCTCTTTAAAAAACCAATAGCAGCCAAAACAGAACATT TGTAAACAAAACCACAACTNTCAGCCCTGTGCTTAAACACAG GGTTCTGCATTCTTTTGGAAACATTAAGGTATATGGCATTAA 63 IMAGE:212772 H69683 3′ NGGGGGTTNTAGGNCCATCTTTNTC GCTTTATCATCATGAAACAAGTCATCAGAGTCTTTGAATCTT GCGTAGGAATTGGAAGTCGGGGTATACCAGGATAGGTTTTCA GCACCAGGTGTGGCACTCACCCTCCGGTATGCTTGGCAGAGT TTGTGAAGCGGCTCCGGTACTGCGAATACCTAGGGAAGTATT TCTGTGACTGCTGCCACTCATATGCAGAGTCGTGCATCCCTG CCCGAATCCTGATGATGTGGGACTTCAAGAAGTACTACGTCA GCAATTTCTCCAAACAGCTGCTCGACAGCATATGGGCACCAG CCCATTTTCAATTTGCTGAGCATCGGCCAAAGCCTGTATTGC GAAAGCCAAGGAGCTGGGACAGAGTTGAAGGAAATTCAGGAG GCAGCTCTTCCATNTTCAAGGAGGTTGTTTGAAGACNGTTAG GTTTTGTAAACAGTGCATTTANAGGGNGTTTCGGAGGCAGGT GGCCGGGNACATTTNGATTGATGNAGTTCCACCTGTTCTTCC CTTTGAGGGACNGGGTCAGGATCAGGAAAGGGGTTGTTGGCA 64 IMAGE:212772 H70099 5′ AACTAC NTTCGGCACAGACTTTTTTTAAGCTACCAATTGTGCCGAGAA AAGCATTTTAGCAATTTATACAATATCATCCAGTACCTTAAA CCCTGATTGTGTATATTCATATATTTTGGATACGCACCCCCC AACTCCCAATACTGGCTCTGTCTGAGTAAGAAACAGAATCCT CTGGAACTTGAGGAAGTGAACATTTCGGTGACTTCCGCATCA GGAAGGCTAGAGTTACCCAGAGCATCAGGCCGCCACAAGTGC CTGCTTTTAGGAGACCGAAGTCCGCAGAACCTGCCTGTGTCC CAGCTTGGAGGCCTGGGTCCTGGGAACTGAGCCGGGGCCCTC ACTGGCCTTCCTTCCAGGGGATGGATCAACAGGGGCAGTGTG GTCTTCCGAATGTCTGGGAAGCTGATGGGAGCTCAGANTTTC CACTGTCAAGAAAGAGGCAGTTAGGAGGGGTTTGGGTGGGGC TTGTTCACCTGGGGGGCCTTCCAGGTAGGGCCCTTTTTAAGT 65 IMAGE:232714 H73130 3′ GGGA GTGGGNCTGTGTTGAAACAGGCCACGTAAAGCAACTCTCTAA AGGTCAAACCACCATAGATTTGAATCTGCTGGTCATTCGCCA TCTGGATTTTTAACTGAATGAATCTCATGGGTTTAACCAAAC ATGCATGTAATCCTGAATACCATGANTTAAATGCGGANTTGC CCAGGGACGAGGAAACCTTCAAGAAACAAGGTCAAAGGGACA NCAGATATAACTGTCACANTAAACANTTCTGTTGACGTGGGA AATGCACATGACTTGGTTGAAACAAAGCTCCTCAGTGGGCCA GTGACATCCNGGGTTTTTCTTAGGGTAGGCTGAGGACTCAGG 66 IMAGE:232714 H74208 5′ GGCTTATCTCACCTTCTCAGGAATGCTTTTTGAAGG TTGCTTACATGGGCATCCTTCAGCTTTTAATAATCTGAAAAA CTCTATTTACCCATTGTCAATGTGTATAAATTAATCTGAGTC AATTTTATACAATAAAAGGTGAACTTTTATGCATGAAACAAT AATTTAACAAGAAATGTACCTGAAGAAGAATGTTCATTACAA ATATAGGANACATAAATATTACCAAATATTGGCAAGCACTAA AATGTTCAGAAATATAAGTCTATTACAGTTATAGCTCTCTCA AGCAAAAAAACAGCAGAGAAAAACTTAGTTTACCTTAGGGGC TATTTATTTACTTAGGGATTTGTTAAAAGGTCGAATGGGGTC ACACAGAATACTAAGAAGAGCTGTTCACCCAGGCCTCACTAA GAACTCTTCTTCATTCAGTAGCTGTATAGTAACATGACAACT 67 IMAGE:234376 N28268 GGCTCCTACGACCCAA ATTACTTGCAAATTAAGTTACCACAGACTCTGGTAGTGTNCT AAATNGCGCCAAGGCNTGGGCNCACAGCNCAGTAGCAGNCTG GNCGNCAGGGCCACTGGCCNACCAGTGACGGACATGCACGTG GCAGATCATGATTTCCAGCCCACGGAGCCAGCATTTGAACCT TGTATAATTAACTTTCAGTTATGATTTCCCATCGACATTTTC TTTGCCCTGTTTGTAGCTGATTGTTGTGTTTTATAAATCTTC TGTTAAGGCAGAAGGGTGATTATGAGTGGTTCACAGCAGCCC TTATAAGCTGGGCCAGAAAATTTCACTAGGGTCAGTAATTTA 68 IMAGE:240367 H89996 3′ AACCTTGGTTCTTC GTTTTTTTAGCACTTGTTAATCCGTTATGATTTATTAGCTGT ACAGCAGTAGATCCTCCTCCCCAGCTTTCAACCCCATTACAT ATTTTATTACAGGTCTCATGTTGGCGTCCTAAAATAATGAAA AATATCACACAGTACAGCTAAGTACAAAATGCATCAACCTAG AGTCTGATAGCTAACTGATGGCTCTCTTAAAAGCAATACACA GANGANAAAAGTGTTTGAAATCAGTAAGACTGAGGCTCTCTA AAAAACACATTTTTAAACATGTGACAGTTCATGTGNCAAGGA NTCACTTTTTAGTTGGGTTTTGGCTTTCACATTATTTTATTT 69 IMAGE:240367 H90086 5′ TTTGAGGATCCAGGGTTTAAATTACTGACCTGGT GTCCTTTGCATAATGCATGGCAAAATGAGCCTAAAACCTATA TGGCCATTTTAATTTTGCTTTTGTAATAATACCAAGCCCAGT TTCTTTCAACTTGAGAGATGAGCTATTTATTCTTTTACTTAA TGAAGATGTAAGAAATGATCTTCTGTTCTAAAAAAAAAAAAA TTTCTCTGATGTCTCTTGACCCTGTAGAAACACATTCAGTTT CTACACTGCAAAACAGAGGGATATCTGTATGGCTTCCCTCTT TCCATCTTTCCTTTCCTCAGGGAAAGCTAGGAAAAAGAAATC TTTTCTATCACAGCAGACACACCAAATCTCCCTAAGTTGTAC CACCTTAATTCCTCAGAATGGCAATTGTGTATGGATACCAAG CTACAACTTGGATAAGAAATTGGTGATTTTCTTCTTTNAATT 70 IMAGE:244058 N38809 3′ TTCATTCTCCAATTTTAAAAACATCTATTGGCG GTAGTGTTTTGGGCACACCTAAGGTCGATCTGTGTTGTATTT AAAAATCTAATTTCTTTATTTGTGTGGCCTTCTAGACAAACG AAGGGGACCAGAGGAAACCCCCTGACAGATCTCTGGATGATC CTCCTTGAATCCTGGGCAGTTTGGTCTCTCCTTGNTGTGCTC CTGTGGCANAAACTCCCTTTGATTGGTTCTTTCTTTCCTTCC CAGCTAGACTAAGCCCCTCATGGGCAGGTAATGAAGATTGAA AACTTTTTTCTGGTCTCCAGTGTGAGCACATTCCTCCTACAT 71 IMAGE:244058 N45440 5′ GGTAGATGTNCCAT TACTACTCATAACAGTTTATTTTTACTTTGTACAAAATACAA AAATGCAAATCCAAGGAGTACAGACCAGTAGTGACAGGCACA CTGCACAACAGCAACCTTGTCTAGCAAGACAGGAGTTTTTTA AATTTTATTTTAGTGAATAAATGCATTATATAAAACAACAAC AACAACAACAACAAAAACACAAAGAGGCTAGAGATTTCACCG TTTCTACCCCCAAAATAACGCTTGCTATCAAGACTTTGGAGG GGGATGGGGGAAAAGAATTTAAAAGGCAAATAATTTTTTTTC ATAAAAAGTAAAAGCTACCATAAAACATTTTTTTTTCTGTCA CTGATTAAATTTCTTCTGAAAAGCCGCACATATAGACAAAAC AAAACAAAAATTCCTGAACTGGACCAACAGCCAATACTCCCA 72 IMAGE:246722 N57754 3′ GGGGTGTTAACC GCCATCATCCCACACATCAGCACCAAGACCATAGACAGCTGG ATGAGCATCATGGTGCCCAAGAGGGTGCAGGTGATCCTGCCC AAGTTCACAGCTGTAGCACAAACAGATTTGAAGGAGCCGCTG AAAGTTCTTGGCATTACTGACATGTTTGATTCATCAAAGGCA AATTTTTGCAAAAATAACAAGGTCAGAAAACCTCCATGTTTC TCATATCTTGCAAAAAGCAAAAATTGAAGTCAGTGAAGATGG AACCAAAGCTTCAGCAGCAACAACTGCAATTCTCATTGCCAA GATCATCGCCTTCCCTGGGTTTATAGTAGACAGAACCTTTTT CTGGTTTTCCATCCGGNCATTAATCCCTACANGGTGGCTGTG 73 IMAGE:246722 N59721 5′ TTATTCATGGGGCAGGTTAAACAAACCCCTGGA AAGGATAAATGCTTTATTCTTTCTGTTAATTCATCGTTTTCA AATGAATGAGATAATGCCCTAGAAACCTCCAAAAGGTACCAA GGAGGTGAGTGTGTGTATATAATCATAAACTCAGATTTCTAT ATATTTATATACATTGTGGTCATTATTTGTTTTGATGGCCAT ATTGTCTCATTTTAGGTTAGTGGGAGCTCCTTAATATTGCTC CCCTGTTTTTGTGACATGATTCATTAATCTTTGATAGCTTCC TTGATTTCTGGAGTAAGATGGCCCAAGTTTATTTTACATATT TCCTGCCCCAGACCTGGATTCAGCTATTCTCCTAAGAGCACT GGTTCTTAGGAACCAGTNGAGTAATAGTATGGAGAGACCACA GTCTTGGATGTTCATTGGTAACTACTGGCTACTGAGTTGGCA 74 IMAGE:258118 N27108 3′ TTACTTCCAGGAC TAATCCTAGATTATCTTTATTTGTTCTATAATTTAATAGTAT ACCTATAAAATAATTACATTATACTTATAGCTTTTCTTCATT TATAAACAANACAAAAAAATTAAATACAATTTGAGCCATTAT AAGGTAAACTTTGTACATACGNTAACCCCAGAAGGAGCTTCA CACTGCAGCATATCATATTGCTTTCATTGCTACACCCACAAT TGGGTTCGAAGAGAGTGTGCTCGTGTTTGCATTCTGTAAGTT CTTAGCTTAATCCCTCCCCTATCTGTGTGGGTTCCATGTTAA 75 IMAGE:258242 N30655 3′ TAAAATGATAGGGGTTGGCTTTGCAGCTGGNCAGAGAC CATAATACAGTTTTATAGTTTAATGGACAATGTTTAACATGG TACCTCTCAAATCTGATATATCTTGTGGTGCTTACAATTTGC CTTACACTTTCATTTAAAGTTACCCTGTTCTCCACTCACCAC ATGTATAAAATATCCTATTTTTTCTCTTAATGTTTTACAAAC CGGTAATTTTCACTATCAGTAGCGGATCTTTTTATAACTCAC CCTATGTTGCCCAAAATACACCAATAATATAATGATTAGATT AAAAAACTTGGCATCTTTTTTAAAAAAATGTGCTTTCTTTTC CATGTATAAGATTCTACTATACCATTTGTGAATGACACCCTA GTTACATAACACCTACATATCTGCCCCTGTGAGAATTTACCT TAGTCTTCTAAGACTCTATCTTCAACAGTTAGATAAGTCAAT AACCAGAGTTCCAAGAAAAGTAGTTACTTTTTAAGACCAAAT 76 IMAGE:259902 N32912 3′ TATTGGGATAACTGGGTC TGGATCCTATAAACCTGTCAATTCTGTTCCTTTTGAGGATGG CCACACAGACAACCACTTACCTCTTTTAGAAAATAATACACA TTAACACCTCCCGATTGAAGGAGAAAAACTTTTTGCCTGAGA CATAAAACCTTTTTTTAATAATAAAATATTGTGCAATATATT CAAAGAAAAGAAAACACAAATAAGCAGAAAACATACTTATTT 77 IMAGE:259902 N42054 5′ TAAA AGCAGCACCTTTTTGGCTTTTTAATGCTTGGCTTGCTTATAT CTTTGTCTGTAAAAGAATCTAATAGTTTAAAGCAAGAAAAAT TCCTAGTCTGCAATTAAATACGTATGGCAACTATGTGGAATA CTAATCAAATCTTTGGTGTCCTTTCTAAGGTAAATTCATTTT TCTACCTCAGTTCAATCTTCATTATCATTTTACATTCCACTG GAGGCCCAGCTAGCACAACAATGGCCAGCTCTTGCCTGAATC CCGAAAATTAGACTTATATAAATGATACCCCCAGAAAGACTC GGGGTAATCTCAAAACAGGAGACCAATTTTTGATGCTGGCTT GCATTCTTGCTTTCTTGGTCATTTTGCTTTTAGTAGGCCAAA GCTAATACTTCTCCAGTGGGAATTTCAGATGGTTGGACATTG GATGGGAACAAAGAACATATTTAAGGAAAATTAAATTTCCNG GGTAGTAAAGTTTATAAACTTTGGAAATCCNTAGACTGGGCT TAAACTTTCACTGGGTAAATTCNCAATAATGGNAACACCTTG 78 IMAGE:265294 N20848 3′ GCCAAAGATGCTATATAC AGCATATTAGTCTATCAAATCCAACTACCCTTAATGCCAGTGA ATGTTAAAAGTAAAACTTTCTTAGCACTGACAATTTAATAAGT AAAAATAAGTGGTACTAAGCTTACAAAAATTAGCTGAATTGGG GAAATTGTTGATAAGGCCACAAGTATTAACATGTTATACTTGC TTGCTTTGAGGGTATATAGCATCTTTTGGCAAAGTGTTACATT ATTGTGAATTTAACAGTGAAAGTTTAAGCCAGTCTAGGATTTC AAAGTTTATAACTTTACTACCAGGAAATTAATTTACTTAAATA TGTTCTTTGTTTCCATCAATGTCAACATCTGAAATTCCACTGG AGAAGTATTAGCTTTGGCCTACTAAAAGCAAAATGACAAGAAG CAAGAATGCAAGCCAGCATCAAAAATTGGTCTCCTGTTTTGAG ATTACCCCGAGTCTTTCTGGGGGTATCATTTATATAAGTCTAA 79 IMAGE:265294 N27686 5′ TTTTCGGGATTCAGGCAAGAGCTG NGACAGTTGATTATTTATTTGAATAAAAAATTCAATTAGATTT CTATCACACACAATAGACACAAACAAATTAAAGGTGGATTAGG GGCTAAATACATGCATATACATGTATACACACACATACACACA GATATATATGCATATACATATATTCACACACATAAACACATAC ATATATTTTTTAAGGGAAAAAAACAATAAAATTAAAACTTAGA AGTATATATATGTAAACTGTGATCTGGTTTCAAGATTATGAAA GGCTTTCTAAATAGCTTAAAGTAGAAATCACAACAGTAAAAGA TAATCTGATTATAAATAAAAAAGAGGGAAAACCTTTTTATGTA AAGAAGACCATAAAATTTAAAAGGCAAATAATAAACTGGGGGA 80 IMAGE:278944 N63049 3′ AATACCTGGCAAAATATATTCATATCCNAAATATACCAAGAGT AGCTTCATTAAAATCTTGGGAAATTTTAATTTGCATTCACCTT CTCTAAACATGAACATGAATCTGTAAAGTGATACATTCTTTCT TGCTTAAGAAATTAAAGCGTTTGGGGATTTGAGTTTTTATACT CTTTGAAAATTGAGTTTCTTGTGCTAAAATCATCATTCACAAA ATGTCCTCTCACCTGAGGAATTCCAACACAGCAAATTCAATCT GAAATAAATTGAGGCTACATTTAAGAGACGGGACTTCCAGCTA AAAATAGGTATTAGAGAGCTGTTTTTGCCAAAAAATTGAATAC TTAACCTTATTCTTCACTCTTGACTCATTTGTTTTGTCTCAGT NTGGGTGACTGGAGGGTTTCTTCTTTGTATTTNCATTCTGTAT 81 IMAGE:278944 W00554 5′ CCATTTCTTAATGCGATTGAATTAGANACCATTTTATG TATTTAAAGCACATTTTTATTATAGATAGGTTAAGTGTGGTTT GCTGTGGCTAAAGATATATTTATAATGGATGAACAAGCTTTTC TAGATACCAAGAGGTATAATATTTTTCTTTCAGTATTGAACTA ACATTTCNCTGATAACAAGGAGACATTGAACTGGCTGAGCCTA TTTTAAATGGGAAAAGACTTTTTTTTTCTGGATGTTGCTTTAA 82 IMAGE:280567 N51674 3′ AGACTGGNAAATTAAAAATTTTAAAGTACCA GTCATGTCAGTAATTTATTTCAGGGTCTAACAAATATTACCAC AGCAGTTTAGTCTCAAAGTGATACAAAACTGAACTCAGGGTGG TTACTGGGTAGTCCCTAGTCCAAAAGATTAAGACACACCTCTA ATACACACACAGGCTGTGTTCAAGGCCTTTTCCTTCCCATCTT CTGGTTCTGTCTCCACCCTTTCCAACTGATAGCACTTCATTGG TGTGTGTGATATATGTGATTATCTTAAGCTAGAAAGTACAACA GAAGGAGAGGATGGTTGTCACTTGGGGATTAGACAGTTGAGAG GATAGGAAAGGAGTTATATCCACCAATACAAGCCCTTCTTCCC CTCCTACTTAGAAAGAGGGTGGGACCATTGGCATTCCTTTTCT AAGAAGCCCCTCAGCAAGGAGTCTGTTCCAAGAGAATATAACC 83 IMAGE:284584 N59450 3′ CGNACTANGAAC GAGTTTGTTTGAAGCACACCTTTAACTCAGAATTGAGGTTGAC TGATAAAACTCAGCTTTAAGTAACCCTCTGGGCAAGTTCTGAG CAGAGATCCAGTGAGCTGAATGTCAGGCACCACCTCCCTGGAG TCTGTATCAGTCACATCAGCATTCTCCTCTGATTAGAATCAGG TTTCAAGGGTCTTGTTCAAGAGTTTATTCTCTCCTTTAAAGAT GCCACAATACCGTATAAGGAATGTCTCTTGGTCCCAACTAATC TACAATAAGAGAGGAGCACGTATAGTCAGAGGGCAAGAAAACA ACCGCAGTTTCTAAGTTTCAGGTTATATTCTCTTGGGAACAGA CTCCTTGCTGGAGGGGGTTCNAGGAAAAGGGAATGNAATGGGT 84 IMAGE:284584 N71839 5′ CCACCTCTTTCTAAGT ATTAAATAGAATTTAATACTTTATTAAATTTTATTAATGTTTA CTTCTACCTGTTTAGACTATTTTTAAGGAATGTAGACATCAGT ACTACTCGAAGTGTGGTCCCATATTGATCCCATATTGATCAAC TGTCATTGGCTGATGGAGAGATAAGCACATAAAGTGAGCAAAC ATGCATAAACATTTAGAAATGCTGATAGTAAACTGACAGTGCC AATGCATTCAAGTACATGATTTTGTATTTACNAAAAGTATCCT 85 IMAGE:287721 N62231 3′ TTTATGAATGGGTTTAGAATT GGCGTGAAACTGNTNCTCTACTAAAAATACAAAAAATAGTGGG GCATGGTGGCGCATTCCTGTAATCTCAGCTACTCGGGAGGCTG AGACAGGAGAATCACTTGAACCCGGGAGCAGAGGTTGCAGTGA GCCGAGACTGCACCACTGCAGTCCAGCCTGGGCAACAGAGCGG GACTCGGTCTCAAAAAAAAAAAAAAATGAATAAGACAGTAGTC TCACCTCCAGGAACATAACCTAGATGNNGTANAGNCGNCGAAC GGNTNAGCNGGTNTGNGNCNACTAATNTTNCACAGGGTAATTG AGGCAGAGTGGGACTCTAAAGGGTCTAAGATATTTACAAGGGG TGCTAGAGGAAAGAANGAGAATATATAGGGTCCAAAAGACTTT ATTTTCTTAGGGGAGTTTTACATCATCTCCCCACAGGCAGAAG CCCTGGGTTATGTGACTATGCCAGTAATTGAGTGGTTTAATCT CCAGTTTAGGGATATGGGGTATTTAACCAGTCCCTGTTGCTAC AGATTGAAAAGACATATTCTTTAATTTTGCTAACAATTAAAGG TGATGTTTGATCTCCNGGAGTAACTTCTCCATCTTCAGGGGGT TTCCAAATTCTGGNGGGAAATNCAGGGGTGTTNCCCATTTTTA 86 IMAGE:287721 N79323 5′ TCATTNGGATC CATTTTAATTCACTGAACTATATTTTTTGGTACATTACCCTTC AACTAAAAAAATAAAATTAAAACATTTCCCTATTACTGATGAA GGTTAGAATGAAGAGAACATAAGGTATATAAGTAGGAAAGAAA ACCTATGTAGGGACAGATGTTAATAGTTATTAAATCCTAAGTA AAATTTTCAGAACTTGGAAATTACCAAATCCAGGAGTGGTCAG ATTCCTTTATGAAGGTAGATCTGGAGCTACTTAGGCCAGATTT TTGTATTTTAGCAAAGTTCCTCAGATGATTCTGACGCACACCT GGATTATAAACCACTAAACCACTGAACTACCCCAAGAAGGTTA CGTGACCTCCCAGAGCTAGAATGTNCCAGAAATGGTGCAAGAA 87 IMAGE:288736 N59214 3′ TTCNATTACTGGACTCCTGGCCC GAAATCACAACAAACTGAATTAAACATGAAAGAACCCAAGACA TCATGTATCGCATATTAGTTAATCTCCTCAGACAGTAACCATG GGGAAGAAATCTGGTCTAATTTATTAATCTAAAAAAGGAGAAT TGAATTCTGGAAACTCCTGACAAGTTATTACTCGTCTCTGGCA TTTGTTTCCTCATCTTTAAAATGAATAGGTAGGTTAGTAGCCC NNNAGNGTCTNAATNCTTTANGATGCTATGGTTTGCCATTATT TAATAAATGACAAATGTACTTAATGCTATACTGGAAATGTAAA ATTGAAAATATGTTGGAAAAAAGATTCTGTCTTATAGGGTAAA AAAAGCCACCGTGATAGAAAAAAAATCTTTTTGATAAGCACAT TAAAGTTAATAGAACTTACTGATATTCCTGGTCTAGTGGGTAT 88 IMAGE:288736 N75239 5′ AATA CAGGTTTTTATTATTTATTATTATTGTTTGTTTTGAGATGCAA TCTTGCTCTGTCACGCAGGTTGGTGTGCAATGGTGCGATCTTG GCTCACTACAACCTCCGCCTCACGGGTTCAAGCAATTCTCCTG CCTCAGCCTCCCAAGTAGCTGGGATGATGGGCGTCCGCGCCGT GCCTGGGTAAATTTCTGCATTTTTAGTCCAGATGGGGTTTCAC CATGTTGGGCAGGCTGGTCTTGAACTCCTGACCTCAGGTGATC CGCCTGCCTTGGCTCCCAAAGTGCTGGGATTACAGGCGTGCAA CCCGCGCCTGGCCCCAAATGTCATGTTTTTAAATAAAAACATA GAAAATGATATAAAGGTTCACAGCATCATCAAGAAAACAGTTC 89 IMAGE:289337 N92646 3′ CCCCGTGTCGCGGAGGGGAGATG GCAGNGGGAACGTCTTCTCATGCTCCGTGATGCATGAGGGTCT GCACAACCACTACACGCAGAAGAGCCTCTCCCTGTCTCCGGGT AAATGAGTGCGACGGCCGGCAAGCCCCCGCTCCCCGGGCTCTC GCGGTCGCACGAGGATGCTTGGCACGTACCCCGTGTACATACT TCCCGGGCGCCCATCATGGAAATAAAGCACCCAGCGCTGCCCT 90 IMAGE:289337 N99582 5′ GGGCCCTGC AAAATAAAGAATCAGATTTATTGGGGTGGTTAAGTGAGATCAT GGATGAACTGTTTACTTCTATTCAGCAGTAGCCTTTGTGGTCC CAGGCTTCTGGTGGCCAGATAATTCCCTCAACTCCATGAGCAG 91 IMAGE:290749 N71796 3′ GTGACCGAGGAGGACTCTCACATCCTGCATGTGTTTNAGA AAGTTTTGCCACTAACTTTAATGTATCATTAGGCAAATTATC CTCTCTGAGCCAAAGAAGGGTAGTGGGATTACGGGATCTCCA AGGATCGTTCTTCTTAACATTGTCTGATGGCATAATTGTCTT ATTAAGATTTCTAGGGAGAAATACAAAGTTAAAAATAAAATC ATATAGGTTAAAATTATGTAAACATCTGGCCTAGAGCCTCTT GATTCAACTCACATAACTAACCAGACCATGGGGGCCAACAGG TCAAAGGACACTATGTAAAAGACATGACTTAGACACATGGAG TGAGAGGAGCAACACAGGCTCCCATGGGTGGGGACTGAGCTG GAAGGTCACAGTAATGAGTGAACTCCCCCTTGGGCACACTTT AGTATGATGAGTAAAGCTTCCCTGGTGACTTTAGAGAATGGA 92 IMAGE:293005 N69118 3′ TCATGGGAACACCTTTATAAGAAG GGGGATCTGCCTGAAGCAGGGATGGGACACNAAGTCCCTCCA GCTTATCTNTNCACAACAACCCTTTCCCTGCAGANATGGTTT GTATACCACAAGCCCTCTTAGCACGCAAAAGCCAAAATCTAA AGATCAACCATTTATCCTGAACAACACCATTTGAGAAAGAGG TAACCATCTTTGGTTCTACATGGTTTGGAGAGTATAGTGGTA GGAGGGGCTCCCTGATTCCCCTAAAGCTATGCACACCACAAG GGGCTCTGCTCTTCTGTCTGGGATCTTCTTATAAAGTGTTCC CATGATCATTCTCTAAAAGTCACAAGGAAGCTTTACTCATCA TACTAAGTGTGCCCAAGGGGGAAGTTCACTCATTACTGTGAC CTTCCAGCTCAGTCCCCACCCAATGGGAAGCCTGTGTTGGTT CTCTCACTCCATGTGTCTAAGTCATGTCCTTTACATAGTGTC NTTGAACTGGTGGGCCCCATGGTCTGGGTAGTTATGTGAGTT 93 IMAGE:293005 N90642 5′ GAATCAAA CATGATCATTCTTTTTAATGTGCACCAAATTAGCAGTAAAAA TAGCAGCAGATGGATCAGAGTGGTTGTCAATAAACCTTTTCT CCCCAGGTTACTAATATACAATTGCCATGAAAAATAAAAAAA TATATATATATATTTACACTTGACTCATCACCTCTGCTTAGG ACCCTGTAAGCACAAGATATTGCTGAACTGCTGTATTTGCTA CATATGGAACAATTAGACTAGCAATAAGAAGTAGTTTATGCA TGTATGCTGGCCTACATGNATATACCCCTTTCCGCAATTACT GAGGATTATCAACAAAGTTTGGTCTTGGTCTTGTGATTATAA TNCCAATNAAATNACATNTTAAATGGGGATATCNCCGAATTN TGGTTTTNATAATTACGTAATTAATTCCNAAGAAATTAAATA 94 IMAGE:294647 N69453 3′ GGTAATATAGACCCCTGTAAAAANTAACCNT AGGAAGGCCAGAGTATTAATATCCCCATCTGTGTCTTTTGCC TTCCATGAACCTGGGTTTTGAGCCCTCTCTTGTAAAATGGGC ACAGTAATATTACCTACCTCAGGGAGTTGTGAGGATTAAACA TGAAGTGCTAAGCATAGTGCCTGGTACAAAGACAGTACTCAA TAAGTGCTACCTAAAACTAGTATTCATAGCAATACTGTTAGG ATAAAGAATTATCATATATGAGATAGTTCCAAATTTTTGTTT TTTTAAAAAAAAAAGAGTTTTATAAGTTCAAGATAATATTTT CTTACTTCAAAGAAACAATCTCACAACGAGGGAATGGTAAGA ATCAGGAGAGATTACTAACCTGGCAGAGGAGCTATCACAATC ACAAAGGTGGTTTTTCCAGGGCACGGCTCATCCATTACACTC 95 IMAGE:294647 W03283 5′ CAGATGTGCTGACCC TCAGTTTACAATGCATAATGATATGTCTTTATTTCATCAACA GAAATGGTGTCTAGACAAAATTCAGTTAACACTAGCAATTCA ATTGAGTGAAAACTTTTTTTGCACAATAGTGTATTTACAATG AGTAAATGAAGTTTCAATTCATTAGTTCATAGCAATGCTTTT TTCCCCCAAAAGGTAAAAATTCTTAGTTACAGAGAATAAGCA TCAACAGCCTTTCATTTTTTACAATNAAAACCNCGGGNAAAA CCNCAATCCCCTTTGGAAAAAAATTANGGGCCAGGCCTAGGA CCTAGGTNCAATAAAATGGATGGCATTGGAATTAAATTTCCA 96 IMAGE:296483 N74648 3′ TTAATCGGCATAGGAATCCCGNGGTAAAANGTTTGGTAGGAA ATGTCTACAAGGTTTTATTAAAATTAAGTTTAACATTAATAA CACACTAATATAAAGGTAAAATTTAGCTTATCTGGTATAAAA GTCATACAGGAAGCATTAGTAAATATAAAATAGCGTTTAGCT TTCTTTTGTCTAAAAACTAATAAAAATTGGTGCTAAAGGAAG CATTCATTTTACTAGAGGATCATAAAAGTTAAAGACTTAAAA CAAACTTTGGCAATTAAGACAGCATACCAAGATGCAAATGCC TGGTTGAAATGGATCAAATATTCCATCTGCAGGTTAAACAAA AGCAATTAGCATGCTTGTGCACATGGCAGGCCAGAGACCCTG ATTGTCCCCCTTCCACTAAGGTGGTCCTCCAGTCGGGCCAGG CATGGGCTGCATGGTAGCTCTTTTCCAGGATTCTATAGCCTG 97 IMAGE:296488 N70208 5′ GAGTAATAAGTCATGCCAAGCTCTCTCCTGCTATATN TTTTTTTGACTCTTATCTAACTTTACTTCCAAACAATGATTT ATAAAATGTGGAGGAGAGTGGGTGTCTATGTCAAGCAGCCTT ATGATAAGGCTCCGTCATATATTGTGCTTATTCAACAATACT GGTGTTAATGAGGCCTGGCCTCCAAAGGACAAAGATACAGAA ACAGAAAGGTTTTCCCAGGCCAGAAGTATTAGTTTACATCAC AACATTAAAGCATAATACACTGTGGGCCTAAAAATTAAACTG CATGTGTTCTAGCAGCAGGAACAACAACAACAACAACAAAAT GCTTTCACATTTATATAAAAATGACAAAGTAAAAAGCAGAGA ACACAGTGAAAAGTGTCTGGCAGTTCATTAAAATACAGTTGA GTTGCTTCTATAGTCTCAAACCATTATTATATTATTTGAATG AGAAAGAGTATGAGGATTTAACTGGCTGAATTCCATTCCTAC CCCTTATTCATAGGGGAATAATTACCCTGATATTATTTAAAA GTGTTTGCTTTACNCAAAANTAAATAACCTTAAATATTTAAA 98 IMAGE:305302 N95059 3′ AT TTTTTTCCAGGAAAAAAATTAAATCTTTATTTTTAAAAATCC CACAAATCCATAATGAAATCATCATCTGAAAAAAAAGATGGT AGGGAACAAAACGTGGGATACATTTAAAAGGCACTAGATTCA TTAATACCAGAGCCATTCTGGAGATGCCATGTAAGAAATCTG GAGTTACTCTAAATCTTCTTCTTAGTGGTATCAGAACTGGGG AGAAGGGTCCAAGCAAAGTGTTGCCTTTGCCAGTGTATTCGG ATCGAGGTTATGAGGAAGAGCCCTTTTCCTTTGTCAGTGAGT TTCATGTTGGTCCACCACTCCAGCGCTGACAGCTCCCCGATG GCCCTGTCATCGTATCTCAGGACCTCCTTCAGGATGTGCGTT GTGTGCTGCCGACAGGGGGGCGGCCTGGCTCTGACACTTGAN 99 IMAGE:309499 N99256 3′ TTACTGTACTCACACTGGGCTATGAAGTACACAGTTAGA TCATAGGCCCAGCTGTGAGATACAGTAAGTTCAAGATGTCAG AGGCCAGGCCGNCCCCCCTGCTCGGGCAGCACACAACGCACA TCCTGAAGGAGGTCCTGAGATACGATGACAGGGCCATCGGGG AGCTGCTCAGCGCTNGGAGTGGTGGACCAACATGAAACTCAC TGACAAAGGAAAAGGGCTCTTCCTCATAACCTCGATCCGAAT ACACTGGCAAAGGCAACACTTTGCTTGGACCCTTCTCCCCAG TTCTGATACCACTAAGAAGAAGATTTAGAGTAACTCCAGATT TCTTACATGGCATCTCCAGAATGGCTCTGGTATTAATGAATC TAGTGCCTTTTAAATGTATCCCACGTTTTGTTCCCTACCATC TTTTTTTTCAGATGATGATTTCATTATGGATTTGTGGGATTT 100 IMAGE:309499 W30727 5′ TTAAAAATAAAGATTTAATTTTT ACATTTACTAGTTTATTGAATATGAGGTTTATCCATTTAGCA ATGTAAGGAAAACTTTAGTTCTGTTTCTCAGTTATCAGGAGT GAACATAAAACTATTCTAAACCACAATTAGTTTACCAGCATA GTACAAAATAAAATNGACAACTAACGAAATAAAGCAATTAAA GTAACTTATTTTTACTCATAAGGTTACCATAATAATAAAAAT TCCTTTAATTTTCAAAGCACTCTTCATGAAAANGTAGTTGGG GGAAAATTACTATTTGTTCCAANGTAGGATAAAAGGGNAGGG 101 IMAGE:321886 W37628 3′ ATGCNCCCAANTTAAACATTTTTATTNAAAAATTAAACCCCCC GATTGAAATACCATCAGAGGCCCAAGCTCTCTTTTCCAGAGA GCAGTGGCTTTTGTAATAATTCACTATCTTAGAGTGAAAAAG GACTAGACCTGTGTTACATAATAATCTTGGTTCAAGCTGCCC TTCTGAACAAAGATATAAACCTAGCATACATTGTAATAGATA ACTGGTAAAACTGACAACTTTTACTTCTCAGAGGCCATTTAA ATATAATAGGAACCTACTGACCAAACCTAGTGATACATAAAA TTAAAGCCTGTGNACTTTTTAAAGTTGTTAATCACTATACAT ATGTATGTGTATATGTGTATACACATATATAATTTTATGATC AATATCTTAGATATTTTAGAAATTCCCTTTNGAATAGTCTTG 102 IMAGE:321886 W37627 5′ GCGTGCCGTGGAAAAATAGAAAATCAGGGAGATA ATAATTTATTAGATCTAAAGCCCCTTCCTCCCCAGCCCCTGC TTTCATTAAGGTATTTAAACTTGGGGGTTTCACTGCTCTCCC CCATGATGGAGGGAGGGAGCCCCCCAACCTCAGTGAGGAGAG CCCCGAGCCGGCCCCGGGGAAAGAGGGGTGCAGAGGGAGTTC CCCCAGATCAGTACCCCCCACCCCTCCCCAGCTAGTAGCATG ACCAGGAGACGGTTAATGAGAGCCAAGAGGAGTACCTGGTGC ACCTGGTGCGGTGGTGGAGACCTGGGGGGCAGGTGGATCTGG GGCTGTTCCCCCCCCTCCGTTTTTTCCACCCCACAGTTCCTC CTGGGATCTGGCCCTCCAGGGNAAGTGGAGCCTCCAGCCCCT AGGGGATGCATGAGGGGGGAGGGGGTGCTGAGTGGGAGGAAG 103 IMAGE:325024 AA284236 3′ AGTCAGGCTCACAGCTGGGGTGGCCTGGGGGTGGGGGT GTAAAACGCTAATAATTTATTAGATCTAAAGCCCCTTCCTCC CCAGCCCCTGCTTTCATTAAGGTATTTAAACTTGGGGGTTTC ACTGCTCTCCCCCATGATGGANGGAGGGAGCCCCCCAACCTC AGTGAGGAGAGCCCCGAGCCGGCCCCGGGGAAAGAGGGGTGC AGAGGGAGTTCCCCCAGATCAGTACCCCCCACCCCTCCCCAG CTAGTAGCATGACCAAGCNTAGNTTTNATGAGAGCCAAGAGG AGTACCTGGTGCACCTGGTNCGGTGNTGGAAGACCTGGGGGG CAGGTGGATCTGGGGCTGTTCCCCCCCCTCCCGTTTTTTCCA CCCCACAAGTTCCTCCTGGGATCTGGCCCTCCAGGGAAGTGG 104 IMAGE:325024 W49598 5′ AAGCTCCAGCCCCTAGGGGATGCATG CAGCAACATGAAGTTGGCAGCCTTCCTCCTCCTGTGATCCTC ATCATCTTCAGCCTAGAGGTACAAGAGCTTCAGGCTGCAGGA GACCGGCTTTTGGGTACCTGCGTCGAGCTCTGCACAGGTGAC TGGGACTGCAACCCCGGAGACCACTGTGTCAGCAATGGGTGT GGCCATGAGTGTGTTGCAGGGTAAGGACAGGTAAAAACACCA GGCCCTCCCTGCTTTCTGAAACGTTGTTCAGTCTAGATGAAG AGTTATCTTAAGGATCATCTTTCCCTAAGATCGTCATCCCTT CCTGGAGTTCCTATCTTCCAAGATGTGACTGTCTGGAGTTCC TTGACTAGGAAGATGGATGAAAACAGCAAGCCTGTGGATGGA GACTACAGGGGATATGGGAGGCAGGGAAGAGGGGTTGTTTTT 105 IMAGE:325247 AA284262 3′ TTAATAAATCATCATTGTTA CAGCAACATGAAGTTGGCAGCCTTCCTCCTCCTGTGATCCTC ATCATCTTCAGCCTAGAGGTACAAGAGCTTCAGGCTGCAGGA GACCGGCTTTTGGGTACCTGCGTCGAGCTCTGCACAGGTGAC TGGGACTGCAACCCCGGAGACCACTGTGTCAGCAATGGGTGT GGCCATGAGTGTGTTGCAGGGTAAGGACAGGTAAAAACACCA GGCCCTCCCTGCTTTCTGAAACGTTGTTCAGTCTAGATGAAG AGTTATCTTAAGGATCATCTTTCCCTAAGATCGTCATCCCTT CCTGGAGTTCCTATCTTCCAAGATGTGACTGTCTGGAGTTCC TTGACTAGGAAGATGGATGAAAACAGCAAGCCTGTGGATGGA GACTACAGGGGATATGGGAGGCAGGGAAGAGGGGTTGTTTTT 106 IMAGE:325247 W52431 5′ TTAATAAATCATCATTGTTAAAAAGCA TCTGAAGTCACAGCAGCAATACAGAACAAAGAATTTACCTTA ATCTGATCTTTTTACGTGGAATTCCCTGACTCAAACTCAGTG GCTTAGTTTGGAAACCTCTGAATGGCTGGGGAGAGAAAATCT TTTGAAACTAAGTGAATAAATTAACACACACATACGTNGGAA ATCAGCCCTTGTGCAAGTGTAACATGAACATCACTGATGAGA GTGCAGAAACTCCAGGCACCCCTCTGCCTCCTCCTATCCCTG GGCCTGGGGTTGTAGGGAGAAGTCACACTCAATTCATTTCTA GCCACACCATGTCCCTAACAGTGCTAGTGTNAACTAGCCCTG 107 IMAGE:341096 W58202 3′ ACCTGGGTATTGGGTTTAAAGAATGGAGCCTCGTGCC GCTCATTCTTTAAACCAATACCCAGGTCAGGGCTAGTTCACA CTAGCACTGTTAGGGACATGGTGTGGCTAGAAATGAATTGAG TGTGACTTCTCCCTACAACCCCAGGCCCAGGGATAGGAGGAG GCAGAGGGGTGCCTGGAGTTTCTGCACTCTCATCAGTGATGT TCATGTTACACTTGCACAAGGGCTGATTTCCACGTATGTGTG TGTTAATTTATTCACTTAGTTTCAAAAGATTTTCTCTCCCCA GCCATTCAGAAGGTTTCCAAACTAAGCCACTGAGTTTGAGTC AGGGAATTCCACCGTAAAAAAGATCACGATTAAGGTAAATTC 108 IMAGE:341096 W58311 5′ TTTGTTCTGTATTGCTGCTGTGACTTCNGNA TTGTTTTGTTTTCTTTCACAGATTTAATACCGCGATCTCAGC CAAACTCCGGCCGAGAAGTTGAGAAATGTCTTCACCCCCTCT CGACATTCGTTCGTGCTTCTTCGCCTTGGTGGAGCGATAGGG GCGAGCAGGGGTGGGGCCGGCTGGTGCTGCTACGAGGGCCGT GCAGCGNTTNAATAAGTGACATAAAATGTCTACACGCATAAG TAACCGTACTTAGGGCTTCTGCAAGGGCCACCAGAGCGCCTA AGGTGGCAAGTGGGCCCCGTGTCACNGGCCGCGCTGCAGGCG CTTGCGCAAAGTCTTCCACGCAGCCGTCCAGCCCCATGCGCT CCAGGGCCGCGTAAACGGCTCCGAGGCCCGCGGGTTGCTGCT GGCGCCAGGCTTTGAGCATCTCGTACTGCTGGTCTCGGAAAC GGCCGATTTCCANCTTCAAGGGCTTCGATCTCTGCCTCGCGA AGCCCAGCGTGCCAACGAACTTCTTCCAAGCGCCGNCTGGGA 109 IMAGE:345586 W71984 3′ ACNGCGTCAATCAAGGTCG CACAAGCCCTGGTTACTGCAGATGAAGCTGGGATGGAGGCTC TGACCCCACCACCGGCCACCCATCTGTCACCCTTGGACAGCG CCCACACCCTTCTAGCACCTCCTGACAGCAGTGAGAAGATCT GCACCGTCCAGTTGGTGGGTAACAGCTGGACCCCTGGCTACC CCGAGACCCAGGAGGCGCTCTGCCGCANGTGACATGGTCCTG GGACAGTTGCCCAGCAGANTCTTGGCCCCGCTGCTGCGCCCA CACTCTCGCCAGAGTCCCCAGCCGGCTCGCCAGCCAATGANT GCTGCAGCCGGGCCCGCAGCTCTACGACGTGAATGGACGCGG 110 IMAGE:345586 W76376 5′ TCCCAAGCGCGGCGCTGGAAAGGAAGTTCCGTGCGC CAATTTTTAAAAATGTTTTATTACAAAGCTTCTTTTAAAAAA ATGCTCAGCACATTAACTCAAACTGGAATGACAAACGTTAGG ATGACAGTTTTGGGCAAAGGCTGTGCTTGCTTTTTTAAAAAA TGGGTACATCAATGCTCATTTTAACAACTNGGCATAAAATCC CACTAATTGGCTAATAAAAACAGATACAAATACAGAACATTT AAAGTAATAACAATTCAAGTGCTGGGCTTTTTACAACAAGGG GGTGATAAGGAAAGAAATGAAAATTCACTGCAAACCAGTCTG CTGAACGCATCTGTTAAGGTTTACTGTTTAAAAAAAAAAAAG AAGAAAACAGAAGAAAAAATAAACTGAAATTAGGGCTGCCAA TTGCTACCAACAGAGTGGGTTTGGCTATTACATTTATTTAGC 111 IMAGE:347036 W81129 3′ TCTACTGGAACACCTTACAAGGGCGGAGAAGCCA ACTTGAATTTTTTTAATTTACACTTTTTAGTTTTAATTTTCT TGTATATTTTGCTAGCTATGAGCTTTTAAATAAAATTGAAAG TTCTGGAAAAGTTTGAAATAATGACATAAAAAGAAGCCTTCT TTTTCTGAGACAGCTTGTCTGGTAAGTGGCTTCTCTGTGAAT TGCCTGTAACACATAGTGGCTTCTCCGCCCTTGTAAGGTGTT CAGTAGAGCTAAATAAATGTAATAGCCAAACCCACTCTGTTG GTAGCAATTGGCAGCCCTATTTCAGTTTATTTTTTCTTCTGT TTTCTTCTTNTTTTTTTTTAAACAGTAAACCTTAACAGATGC GTTCAGCAGACTGGTTTGCAGTGAATTTTCATTTCTTTCCTT ATCACCCCCTTGTTGTAAAAAGCCCAGCACTTGAATTGTTAT 112 IMAGE:347036 W81128 5′ TACTTTAAATGGTTCTGTAATTGGTATCNGGC TTTTTTTTCGGTATTTGAATACATTTATTGTGACAAGAATGC TGTTATAAATATTCATAAGCAAAGGCCATCTTTTTATCTAGG AATTGTCAAAGAGAAGATTCCAAATTGGAAGGATACATCTTT TGTAAAATCTGCCACCAATTCCTGCTTTGAGAATAAGCACCT ATTGTAAAATTTCTACTAACATTATAAATGGTCACAGCACAT GCCACTTGATACAATCCAAACTTTGAAATGTTTGACTTCTCA GTGGGCTGTCCCTCTCCACTGCAACCCCCCTTCCTCCAGCCT CCTGAAACATCGCACTATCCTTTCGGTAAGCAATTCCATATA GATAGCTGGGGGGAGGAGGAGTATAACCTGGACCATAGCATC AGGTTACATCAGGTACATTTATTTCTAAAGTCTAATAGAGAA 113 IMAGE:358531 W96155 3′ CAGTTTTTACTGCTTAATAGTAAGAAGCACTGAGAGTGA GTATCCTGCCCAGTGTTGTTTGTAAATAAGAGATTTGGAGCA CTCTGAGTTTACCATTTGTAATAAAGTATATAATTTTTTTAT GTTTTGTTTCTGAAAATTCCAGAAAGGATATTTAAGAAAATA CAATAAACTATTGGAAAGTACTCCCCTAACCTCTTTTCTGCA TCATCTGTAGATACTAGCTATCTAGGTGGAGTTGAAAGAGTT AAGAATGTCGATTAAAATCACTCTCAGTGCTTCTTACTATTA AGCAGTAAAAACTGTTCTCTATTAGACTTTAAGAAATAAAAT GTACCTGATGTACCTGAATGCTATGGTCAGGTTATACCTCCT CCCTCCCCCAAGCTATCTATATGGGAATTTGCTTACCAAANGG 114 IMAGE:358531 W96134 5′ ATAGTGCCGATGTTTC GGTGTAATTAGCATNGGTCAATGCGGGACGATNGAGTGGCTCT GGAAACCTGATGGATTTCCTCGATGAGCCGTTCCCTGATGTGG GGACGTATGAGGACTTCCACACCATCGACTGGCTAAGGGAAAA 115 IMAGE:363058 AA019316 3′ GTCACGGGACACCGACAGACACATG TAAATGACACAGTCAGTGTTTTTCTGAAAATAATTGCCACCT TGTTGCTAATTAAACATGATGGATTCGGGGTCCTGGTTTGCC ATCTGGGCCATATGTCTCAGAACATCCTTTTTTGTGATGATG CCAAGAAGTCTCCNGCTCGGGTCACAAGGAATTGCNGAAGGC CCCAGTTTTCCGGGANGATATNCAACAACGGTTTCAATCGGA 116 IMAGE:363058 AA019413 5′ ATTT TTTAAGCTAGAAAAAGGCCAAAAAGCAAAACCTGAGAAAACA ATACGTGTTGTTTTCTCAGGAAAAGAAAAACCTTCATGACCC TACTGAAGAGCATTGGAGATCAGCTTCCGCTAAGATGCTAGC TTGGCCAAGTCTGTTATATTCACCTGAAAAAGTCTTAGCAGA GAATTTTTGCATTCCCACCCAAAAGCCCTCTCAGCCACTCAA ATGCCTATCTTCTCCAGTCTACAAGTTACATGNTCCCACCCA 117 IMAGE:382773 AA065090 3′ GCAT ACCGAAGCTTAAAGTAGGACAACCATGGAGCCTTCCTGTGGC AGGAGAGACAACAAAGCGCTATTATCCTAAGGTCAAGAGAAG TGTCAGCCTCACCTGATTTTTATTAGTAATGAGGACTTGCCT CAACTCCCTCTTTCTGGAGTGAAGCATCCGAAGAATGCTTGA AGTACCCCTGGGCTTCTCTTAACATTTAAGCAAGCTGTTTTT ATAGCAGCTCTTAATAATAAAGCCCAAATCTCAAGCGGTGCT 118 IMAGE:382773 AA064973 5′ TGAAGTCC TAAGAGGTTGCGAACATACATATTTATTTATAATACAAAATN AAGATTNGAGGGAAAAGTGCTTTAAAAAGTANCATGTAAGTG TATAAATGAAATTNTNGCTTCTTCTCCGATACAATTTTGATT GGGTGAGCATTATTTGCTTTTACAATAATGCTTTATTTTGTT TTTTGCATTGCATTGCACTAACCTGTCCATTAATACAAACAG AAAAAGAAGGTGGAGGACGTGCCCAGCCGCGTGGTCAGCGTG CCGAACCTCGCCTCCTATGCAAAGAACTTTCTGAGTGGCGAT CTGAGTTCCAGGATTAATGCCCCTCCAATAACTACATCACCC AGCTTGGACCCAAGCCCCAGCTGTNGGCCTGGACCCTACAAA CCCANACCAGTCTACAGATTGCAAAAACTGCCACAAGGTTTT 119 IMAGE:417637 W90399 3′ GGGGGGAATGTTTGG AAGATTTTTGTNCCAAGTCCNGTGCTAAGCACATCCTATGGA TTAATTCCTTTAGTCTCACGTCAGTCTGATGAGATAGGTGCT GTATTATCTTAATTTTAAAGGCAAGGTATATGGAGACCTGGA GAGGTCAAGTGACCTGTCCAAGGCCACAGAGCTAAGAATGAG GAAGACTGTAATTTGAATTCAGACCTCCAGGCCAGATGGAGT CCACCTTTTGTATAACCCATGCTGAAGTTTTCAGGTAAGTGA TTCAGTGTCCCTTGTCTAATCATCCATGAAAAAAGGCCTTCT GGAATTTGGTACCAGGTGCTAGAAAGAATCCTACTTCCCCTC TNATCTACANNGNAAANACGNATAAGGGCCCCTGTCCCCAAC 120 IMAGE:417637 W88508 5′ ATCCCCCAAACCTTGTGGCAGTTTTTGCATCTGTAGACT CTATCATTGTGAACTTTTTCCTCTCCTGATCCAGTTCATCAT GGAGGCTCATCATTTCTGTTTCCAAAGTCAAGTTTCGCTGTT CTAAGCTCTTTATCCTGGACTCATACTCTATCTTCTGTTTGG TCATTTCCTGTTTCAGGCTGGAAACTAAACTGTGCAGTGCNT GTGGTTGCTGCTGCTGTTGCCCACAAATGTCTCACTGTTGTC ACTGCTACTGGTGGCACGACTACTTCGACCTCCCACACTCCT GTGGTCACTTTTGCTTTCATAGTCCCTTGGGGTGGGAAAGGT CGTCCTGCGGGGGCCCATCCAAAACAGGGTCCTCAAAGTTCC CCCCAAAAAAGTCTTGCTCTGGGCAGGTGGTGGTAGAAGAGC GACAGGAGTTGGAGTTCTCAGGGAGGGAGATTTCACAGGAGG 121 IMAGE:418185 W90522 3′ AAGTGGACCAGGTAGCACTGNA TTTTTTTTTCACAATTGGAATGTGCTTTATTTCAGGGAAATA TAAAGGGAAATGAATGCTATTATAACTTGGTAGAACAGAAGA AATGGCTACCTAGCTTTGCTTTCCAACTACAAACATAAATGA GGATCTCAGCATTTAAGGTAAAACATGATAAGCACAAAAGGA GAGTTCACTGGGGACTGGACTCCCTCATTTACTCTAGAAATT ATGAGAACCAGCAGCAATATTCCTCAAGCATCCATCTCAACA TCAAGTTCCTTTGTTTTATTTACCAGATGACCAGGGAATCAT AGGATGAGTTTGGGCTGCAACTGTGTCTTCCACTGCCATTCC CAAAGACTTGAACACGGTGGGTCTTCTCACAGTGGGGCTGGG TTCACTTCCCTTAATCACTTTTTCCCAGGTTCAGGCAAAGGN TCTTGGGGCCCCTGGACCAGGCAGGGGACATTTTCCAGGATT 122 IMAGE:42373 R59968 3′ NCTTTCAGGGGGCAG NCGCAGCTCCAGNCTCCTCATCCCGCCTCTAGAGACGNCCCT GGCAAGCTTNTNCAGCGGTCCCGAAGNGGGGGTNATGCAGCC 123 IMAGE:42373 R60419 5′ CGTGCGCANCGTG ACTGAGGTTAGAAGGCACAGGTGGCGAGATGAGCCGGGTACC AGCGTTCCTGAGCGCGGCCGAGGTGGAGGAACACCTCCGCAG CTCCAGCCTCCTCATCCCGCCTCTAGAGACGGCCCTGGCAAC TTCTCCAGCGGTCCCGAAGAGGGGTCATGCAGCCCGTGCGCA CCGTGGTCCGGTGACCAAGCACAGGGGCTACCTGGGGGTCAT GCCCGCCTACAGTGCTGCAGAGGATGCACTGACCACCAAGTT GGTCACCTTCTACGAGGACCGCGGCATCACCTTCGGTCGTCC CTTCCCACCAGGGTAATTGTGGTTACTCTTTTGAGCCCAGCA ATGGGCACCNTGCTNGGCGGTCATGGGATGGGAAATGTTCAT AAATTGCAAAGAGAACAGTTGCATTTTTTGCCNTTTGCCACC 124 IMAGE:42373 R67147 5′ AATTTTTTTG AAAAACAGACATAGTCTCACTGTTGTCCAGATTGGAGTACAG TGACACAATCATAGCTCACTGCAGCCTCAAACTAATGGGATC AAGTGATCCTCCTGCCTCAGCCTCCCAAGTAGCTAAGCCTAC TGGATGCACTACTATGCCCAGCTCACACAGAAGGTTTCTGAG TAATCTGTTGCTCTTTTTCCCTACAATTTGTCTTCCATATAA CTCAAACTGACAAGGCTATGGCTTACATAAAGAAATATATTA TAAATCAACAACACTCATGATAAGTTTACATAAGACATGAGA ATACACCTGAATCACCAACCGGGAAAAATGATTGAAGAGCTT GAAATTAAGCCTAAGTGTAAGTCTCTGTTAAGCTTACAACAT 125 IMAGE:429165 AA005108 3′ TACAATAGTTAAATCG TCTAACCTTCGATTTAACTATTGTAATGTTGTAAGCTTAACA GAGACTTACACTTAGGCTTAATTTCAAGCTCTTCAATCATTT TTCCCGGTTGGTGATTCAGGTGTATTCTCATGTCTTATGTAA ACTTATCATGAGTGTTGTTGATTTATAATATATTTCTTTATG TAAGCCATAGCCTTGTCAGTTTGAGTTATATGGAAGACAAAT TGTAGGGAAAAAGAGCAACAGATTACTCAGAAACCTTCTGTG TGAGCTGGGCATAGTAGTGCATGCCAGTAGNCTTAGCTACTT GGGAGGCTGAGGCAGGAGGATCACTTGATCCCATTAGTTTGA GGCTGCAGTGAGCTATGATTGTGTCACTGTACTCCAATCTGG 126 IMAGE:429165 AA005107 5′ ACAACAGTGAGACT GATCATTCCATCATGTATTGATGCATACAAATATCACATTGT ACCATATAAATTATACAATTATTGTACAAATATATACATCAA TATACAATTGTACATACAATACATACAATTGTTGTACAAATA TATACAATTATTACTTGTCAATTAAAAATTTTAAAAAAGAAA TCTGAAATAACAGTTGCCCCCTATGAGCATCTCACGATAAAT CCCTTTAATCTCCTCTACATATACTGAGTATTAAAAAACAGA ATCGTCTAGAACATTGTTGCTGTTCTGAGACCTGTCTTTCTC ATTTAACACAAGTGAACATTTTTCTTTGTCAGCAAGTAGCGG TAAACATCATCCATTCTAATGGCTGTATTTTTTAATAGGTGG AGTTGTATCTTCAGGGCAGATTCCTAACAGTGGAATGGCTGG 127 IMAGE:429569 AA011448 3′ GTCACAAGGGAAATGTGTAGGTAGTTTTTGGA GTGACAAGCAACCTTAAAAGAGACACAAGGAGACTGGCAGAC AGAGGAAGAAGAGGCAGCAATGTGACCCCGGANGTGGAAATC TCAGTGATGGGGCCAGGAATGTCAAGGAATGGTCAAGGAATG GCTACAGCACCAGAAAAAGAGGCAAAGTGAGGCTTCTCCCCT AGAATCTCTAGGAGCGCTCCAGCCCTGCTGATGTCTAGATTT TTGGAGTTCTGGCCTCCAGAATGTGAGAGAGTAAACTATTGT TTAAAGCTACCAAGTTTGTGGTAACTTGTTAGAGCAGCCACA GGAATGAATGTACAGGGAATCAGGGCAGTCTCATACACTGAT GGTGGGAAAACAAACCGGCACAACCCTTATGGTGGGAAATTT GACAACATTGTACAAAAACTACCTACACATTTCCCTTGTGAC CCAGCCATTCCACTGTTTAGGAATCTGCCCTGAAGATACAAC 128 IMAGE:429569 AA011447 5′ TCCACCTA TTTTTTTTTTTAGTCTAAAGAAAGTTCTGAACAGAATATCAA TTAAGCTTACATCACAAAAACTTTAAATGTATTTACAGAGTG AATAAGTTACATAGATAAACTCTGAATATGTTTCTGCAGTGC AACAAGTTCACATGCACACATCTAACACTTGACAGCATTAAG TTTAAGGAGAGAACTTAAGAATGGCCCTTTACATATATATTA CACATAAAATATGACATCGAAGAAACAAAGTAACAACTCATA TTTTACCTTTATGATTCTACTTCTGACTATCCAAACAGGATA TTAAAATATGGCATGCCTGGACAGGGTGAAAAGACTTGGGGA TTTATCTTGTGGAATAGTTTTCTCTACAAAACGGGCAAAGTT TAATTAAATTTAACNCTTCATTCCTTCCGGCGGTTTNAAATA TGGCTCNTTAAAGGCNACCTTCTGGTTAAAAGGCCGGCCCGG 129 IMAGE:46284 H09111 3′ TTCCCTTNAAAAGG GCCACACTCTCTTNGCTTGCAAATTGTAAGGCAACATTTGCA GGGGGATCAAGAGATGGAGTAATTACCTGTCAACCAGGGGAC TCCGAAGAAAAGCAAATGGAATCTCTTGCACAATTGGAACTG TGTCAGAGATTATATAAGCTACACTTCCAGCTGCTATTGCTT TTTCAGTCCTACTGTAAGCTCATCGGCCAGGGTGCACGAAGT TAGCTCCATGCCAGAGCTGCTGAATATGTCCAGGGGAACTGA GTGACCTAAAGAAACACCTGAAGGAAGCCAGTGCAGTCATTG CAGCTGACCCTCTCTATTTCAGACGGCGCGTNGGTCCGAGCC CACCTTTCACGTNCACTGAAGCAGGCCATCCAGTTCCATGCT 130 IMAGE:46284 H09461 5′ TGGGAGTTGCCTTGAAGGGACCAACGGACT GAAGTAAAAGATTTTTATTGTTCTATAGACACTTCTGAAAAG AGATCTAATTGAGAAAATATACAAAGCATTTAAGAGTTTCAT CCCCAGAGACTGACTGAAGGCGTTACAGCCCTCCTCTCCAAG GCTCAGGGCTGAGAACGGTTAGCATATCGAATGATCAGTAAA AACATGCAAAAGTGAGAAGGAAAGGGAAAAAGGTGCATTCCC CTAAGCTGAGGGGGATGGAATTTCAGAACAGAGGANGCAGGG TGGACAAGTACCAAGGTGGCTCTCCCTTTCCCTCTGTGTNAT 131 IMAGE:471196 AA034213 3′ CTTTCAAAACCANTTCCAAGCNTGGATNAAAGCAA TTTTTTTTTTAGCACACCACAGCCACCATACAGACAGGAGTG CAGCCCCTCCTCCCTAGGAACCCCCACCCCTACTCTTCACTA GGCAGGGCCCATGGCTCATGAATGCAGAACAGTCACCCCAGC CATGGCTGAGCATACCCACTGTTAGTGACACAGAGTTTCCCT GAGAAGAGGCTCCCAAAGGCATACGACAGCCCCTTGGCCACT GCCACAGTAACAGTGCTATCCCTCCTGCCCTTGGANTAGGGG AGGACACAAAGAGCCTAAGGGCTACACTTCAAACTTAGGAGT ACATCACAGCCACCATATGGGAGAGGAGACCAACCTCTTCCT CCCTGTGAGGCCTTTCAACTNCCTGCTCCCCAACAAACAGAA 132 IMAGE:47151 H10995 3′ CCCCAA CAGTACTGCGGCCNNCNCTCCTNTCCNAACCTCGCTCTCGCG 133 IMAGE:47151 H10727 5′ GCCTACCTTTANCCGCCCGCCTGC ATTGAAAATAGATGTTTTATTTTGTTTATACAAGGTACAATG TCAAAATACAAATAATATATAATGTATAGATATAATAGACAA GGAAGTATAAATATAAACGCATATATTCGTAAAATGGCACTG AGTTGAGTTTTCTTCTTCCTGAATCCTTCAATGGAGAGGATT CNCTGGGCTCAGCATCTCTCCCACCTTTCCCAGGTCCCTGTC CATGTGTGCAGAGAGCTGGAGACAGGGTGGTTAGAAGCCCAA ACGCTGGTGTCTTCCCTGTAGACGTCTCCCACGCCAGGAGAA GCCTTGTAATTGACAGAGAGCTTTGGGTATGTCACTTTTCTC TGTGAACTGAAAGTTTAGGATGAGGGCNCGGAANATTCGGGG 134 IMAGE:488019 AA054754 3′ CAGGGTTTT ACNAGCATCCGCCTCCCACCAGCCGCCAGTGTNGTATCCACA GGGCCACAGCGACACCACTGTGGCTATCTCCACGTCCACTGT CCTGCTGTGTNGGCTGAGCGCTGTGTCTCTCCTGGCATGCTA CCTCAAGTCAAGGCAAACTCCCCCGCTGGCCAGCGTTTGAAA 135 IMAGE:488019 AA053285 5′ TGGAAGCCATGGAGGCTCTG CCTTCTTGTTCACTNGGTGTGGTTTATTCTTGAAGCAAGGTC TCTCTCCAGTTGAAGCCCCCAGTTGGTCCATGGGTAAGAGGA AGGATTGGTGGATCTGTCAGCTGCCATATTCCAGTTTCTCCT AATTCTTCACAGGAACAAAATCCCAGATATGGGATCTTTCGG ACCATTTGTACGAAGTCCTTGGAGTTCTGAGGTGACAGGCCC TGAAGTTGGCAGGTACACGCTTCAAGGGAAGATGCGTGGGCC ACAATCAGGATGTTATTTCCTTTACTTTTACATTCACTTATT ATTNCTTTTGTTACTTGGGAAACTTCTACTNGATATAAGTAT CATAGGATTCTGGAAACAACTAATTTNGCTCGATTGGAATGT 136 IMAGE:489047 AA047190 3′ GAGGNCTGGTAGGTTGTATCAACACTCAGGTT CNTTCGGCACGATGGGGAGTATTGGAGAGGCGGCCTTATGAN GNCCANGNGCTCGGGGAGACGACTCCTCTTACTATCATCTGC CAGCCCATGCAGCCGCTGAGGGTCAACANCCANCCCGGCCCC CAGAAGCGATGCCTTTTTGTGTGTCGGCATGGTGAGAGGATG 137 IMAGE:489047 AA047189 5′ GATGTTGT TTTTTTTTTTTCTTCCTTTTTTTTCTTTTAGAAATATTCAAA TTTTAAAACAACAATTAAGTGGATTATGGGAACAGGAAAACC ATCTTACTTTGGTTCCAGGATATACTGGTAATATAGCTAAGG ATGTAGATGCTTATTTATTACAGTTACATTGAGAGATTTCAT CTACTAAAGAGCATTTGGTTTTTCAAAACATCCCTGAACTGT ATAATTTACAAAAAAAAAAAGTCTCGTCTGAGAACTGTGAAC TGTGGAAGAAATCAAAACTATTTTTNCTTTTAAAAAGCCACG TAATGAAACCNCTAATGAAATCCCAGCAATCTGCTTCACATT GAAGTGGAAAAATATCCAAAAGGAGCAGCTTCAATTTTCATT GAGGTGAAAGTGCACTATGAAGATTGTTCACCTTTGGCTGCA TTTGGGAGTTATATGGTTATTTGGTAACNTTAAGAACTNCTG 138 IMAGE:501778 AA127879 3′ GATTTTTAATGCCATCCNGGCATNAAAATATNATTTNTACC TAATAAAACACAATCTTAAAAAAGTTAATGATGATTGGTCTT GGTGGTTCCTAGTGGTAAGTCCTGTCTTATTTTTTCACATAG TATAAATTATATTTTTATGCAGGATTGCATTAAAATCCAGTA GTTCTTAATGTTACCAAATAACCATATAACTCCCAAATGCAG CAAAGGTGAACAATCTTCATAGTGCACTTTCACCTCAATGAA ATTGAAGCTGCTCCTTTTGGATATTTTTCCACTTCAATGTGA AGCAGATTGCTGGGATTTCATTAGTGGTTTCATTACGTGGCT TTTTAAAAGAAAAAATAGTTTTGATTTCTTCCACAGTTCACA GTTCTCAGACCGAGACTTTTTTTTTTTGTAAATTATACAGTT CAGGGATGTTTTGAAAAACCAAATGCTCTTTAGTAGATGAAA TCCCTCAATGGTAACTGGAAATANATAAGCATCCACATCCCT AGCNATATTACCNGGTATATCCNGGAACCCAAGTAAGATGGG TTTCCCGGTCCCCATAATCCNCCTAAATGGTGGTTTAAAAAT 139 IMAGE:501778 AA127929 5′ TGGANTATTCCCAAAGG TTTTTTTTTTAAATGAATGTAACAAGCATTTATTAAAAACTG TGCTGCACAAAACATGTTAGAAACTAGACCAGGTGCTAGGAG TCTAATCAAGGCAGGGGCAGGGTAAAAACATGGGAATATTAC ATGGACAAGCTTGTCTAGCATGGCAGTCTATAACCCTTGAGG GTTTACATAAAATAAAGGAACATTTTTGTGGNCTCAGGCTCC CCAGAGTTCTCTTTATGTTTGGGCAGAGACTGCCCATCCCTT AGTGATCCCACCTTAGAGCCAGGTTTTCAAAGTCATTTCTCC CAGTATATCTGTCTCTGTATGCAAGTTTCCTCTGGTTGCCTT GAGCAAAAACAATCATCCAAGTCAAATTTGCTAGCCCTATGC TGGGCCAGCCCACGTTTCCCGTAGGACATCTGTAGGGTAAGT 140 IMAGE:50214 H16746 3′ TNAGCCCCG TTCCAGAAGGCAAAAAGACATTACCATGAGTAATAAGGGGGC TCCAGGACTCCCTCTAAGTGGAATAGCCTCCCTGTAACTCCA GCTCTGCTCCGTATGCCAAGAGGAGACTTTAATTCTCTTACT GCTTCTTTTCACTTCAGAGCACACTTATGGGCCAAGCCAGGC TTAATGGCTCATGACCTGGAAATAAAATTTAGGACCAATACC TCCTCCAGATCAGATTCTTCTCTTAATTTCATAGATTGTGTT TTTTTTTAAATAGACCTCTCAATTTCTGGAAAACTGCCTTTT ATCTGCCCAGAATTCTAAGCTGGTGCCCCACTGAATCTTGTG TACCTGTGACTAAACAACTACCTCCTCAGTCTGGGTGGGACT TATGTATTTATGACCTTATAGTGTTAATATCTTGAAACATAG GAGGATCTATGTTACTGTAANTAGTGTGATTACTATGGTCTA 141 IMAGE:50214 H16854 5′ GAGAAAAGTCTACCCCTGCTAAGGAGTTCTCATCCCN GCTTTTAACAATGATGATTTATTAAAAGAAACAACCCCTCTT CCCTGCCTCCCATATCCCCTGTAGTCTCCATCCACAGGCTTG CTGTTTTCATCCATCTTCCTAGTCAAGGAACTCCAGACAGTC ACATCTTGGAAGATAGGAACTCCAGGAAGGGATGACGATCTT AGGGAAAGATGATCCTTAAGATAACTCTTCATCTGTCCTTAC CCTGCAACACACTCATGGCCACACCCATTGCTGACACAGTGG TCTCCGGGGTTGCAGTCCCAGTCACCTGTGCAGAGCTCGACG CAGGTACCCAAAAGCCGGTCTCCTGCAGCCTGAAGCTCTTGT ACCTCTAGGCTTGAAGATGATGAGGATTCACAGGAGGAGGAA GGCTGCCAACTTCATGTTGCTGTTGGAAGGCTTTGGAAAAAC ACAGCAGGGCTGAGAGCAGCTGAAATTTATACCTTCCANCCG CTGAGCTGGNATGCNAGGCCAGGGGTGGGACTAGGGGACTGC AGACACCTTAAGNCCTGGCCAGAAACTTGACATTTCTNGAGA 142 IMAGE:503051 AA149250 3′ TTAGCACCACCCTGTGTACCCTGGGTCTT AGGACCCAGGGTACACAGGGTGGGTGGCTATTCTCCAGAAAT GTCAGTTTCTGGGCAGGGCTTAGGTGTCTGCAGTCCCTAGTC CCACCCCTGGCCTTGCATTCCAGCTCAGCGNGTGGAAGGTAT AAATTTCAGCTGCTCTCAGCCCTGCTGTGTTTTTCCAAAGCC TTCCAACAGCAACATGAAGTTGGCAGCCTTCCTCCTCCTGTG ATCCTCATCATCTTCAGCCTAGAGGTACAAGAGCTTCAGGCT GCAGGAAGACCGGCTTTTGGGTACCTGCGTCGAGCTCTGCAC AGGTGACTGGGACTGCAACCCCGGAGACCACTGTGTCAGCAA TGGGTGTGGCCATGAGTGTGTTGCAGGGTAAGGACAGATGAA GAGTTATCTTAAGGATCATCTTTCCCTAAGATCGTCATCCCT TCCTGGAGTTCCTATCTTCCAAGATGTGACTGTCTGGAGTTC CTTGACTAGGAAGATGGATGAAAACAGCAAGCCTGTGGATGG AGACTACAGGGGGATATTGGAAGCAAGGAAGAGGGGTTGTTC 143 IMAGE:503051 AA151535 5′ TTTTAATAAATCATCATTGTTA AAATTGGTTTTAATTTTTTTTAATTGGATCTATCTTCTTCCT TAACATTTCAGTTGGAGTATGTAGCATTTAGCACCACTGGCT CAATGCGCTCACCTAGGTGAGAGTGTGACCAAATCTTAAAGC 144 IMAGE:509823 AA054073 3′ ATTA AGAAATTGACGACTTCACACTATGGACAGCTTTTCCCAAGATG TCAAAACAAGACTCCTCATCATGATAAGGCTCTTACCCCCTTT TAATTTGTCCTTGCTTATGCCTGCCTCTTTCGCTTGGCAGGAT 145 IMAGE:509823 AA054457 5′ GATGCTGTCATTAGTANTTTTT TTTTTTTTTTTTTTTTGATTAACATTCTTTATTTCACAGTATT TTTGATCAGAAGTCTTAGAAATCATGATTCATCTGGTTACAAA TCCCATGAGTTTCTCTTTGAATGAACCTCTTGCTTCCAGTCCC ATACAACGCATCTCCCACCAGCCCCAGTGGGTTGTAACTGTGA TTCAACACTGAGTGCTCGCTTGGAAAGGAGGTGGAGCTCAACT TCCAACTCAGAGGGCCTCTCCCACTGCTCTCAGGGAAATGCCC ATGATTCACTTATGCTGTATCAACAACAAGTGCAGCTGGGCGC TGCCTTTCCCAGCTGGGCCAAGCGGCTCCTAGGGGGGAATCTC CACCCTCAGGAGGGCTTAGGGAAAGGGGAAGGTNTGAACGAGT 146 IMAGE:51406 H18950 3′ TCAGGGGCCCNGG CTCAAAGGGCTGTCACCATCACCTGCTGCTAGGACACTACAAA ACAATCAAATAATTCTTTTCTGTAATCCAATATGCAGCAAGCA AGGGTGACCTCCAGTGGCCCACTCAAGTCCATGAGCCATTATC TAGGATACTTTCTCTCTCTTTCATGCAGTTCAAAGCCCAGGTA TCTCTCAGATCTGCTGCCTGAGAAATAAGCTCCTTTATCAGTT AGCTGTTTTATCATTAGGATACAAGACAGCCCAGTGTCATCA ACAGTGAGCAAATCTGGGCATGGTGTTTGTCTCGTACAGTTG GGGATAGGGAGGCCATTCATTCCCATGGGGGCACAGCTTAAC ATTATCCCCCAGTGGATTACTTTTCGATTACACTTGAAGGAG GACCACCTTGTCTTTTAAAGGTTCANTTTCCNGGGGGTTGGC ANTGTTTCCAACCCAGTTGTTTNCCAGCTGTTTCACAACCAG 147 IMAGE:51406 H19393 5′ TGTGNTGGATT TTTTTTTTCACCTTAGGCAGCTTTTTATTTTGCATCCTTTTT TTCAACTTTGTCTTCTATTAGCTGTNAAGAAATACATGTCTG CTAAAGTTACACGATCTTCGCACAACAGCAACCTACACATTA GTCTACAAAGGGGAACAAACCCAAATTCCTCAGAAGTCTGAG TCCACTGTTGCCTTCTTTCTGGCCATCTGGAGGTTACAATAT AGCACAGAATGACTATGCAAGTTAAATATTCATCTTAGACAT GGACATTTGCTTTGGGACTCCTAAAGTGGAGTCAAATTTGAT CTCTACAGAAACTCTACAATGTAGCAGAGCACTGTGCGTACT TATTGACTCCCGGGACAAGCCGGAAACCCCGGAATTTGTCAT TTCTATCAGGTTTTTATATAAATTGGTTCTTACCTACTTATT 148 IMAGE:53092 R15785 3′ GATGGCTTACAATTTGGGCCATTN TTTTAGGGTGAATCCTATGTGTAGAATTGCTTGGTCAAATGG TAAGCAATAAAAGCAATAAACAGTTGACGCCCTTGATTCGTT TTTCTGTTCAAATGTCAATTCTTTAAAGAGGCCTTTTCTGAT GACTCATGTGAAAAACAGCTCACTGTCATTCTCTGGCTCTTT ACTCTGCTTTATTTTCCTTTGAAGTCCTTATTGGACATCATA TTATCTATTAATTTGCTTATTGTTTATCTTTTCTACTGGACT GTACACCTCATGTGTGTAGGGCATTTGTTTTGCTCACAGCTG TCAGGTATTGGGGATACCCCAATATCTAACACAGTAAACAAT CAAGAATTATTGGGTTGAATTAATGAGTTAATAAAATTAAAT ACTGGCCTCATTGAAGGGGTTATATAGATTTTTAAAAAATAC 149 IMAGE:564567 AA127395 3′ CNGGTTTTGTGCNCCATGGACCCAAACTGG TATTGCCATCTAATGCTCAGAACACACTTGTATTGCAAGAAA ATATTTTTTTGCTTGTTTTTTTGAGACATAGTCTTGCTCTGT TGCCCAGGCTGGAGTGCAGTGGTGATCTTGGCTCACTACAAC CTCCGTCTCCCGAGTTCAAGTGATTCTGGAGCCTCCCAAGTA GCTGGGACTACAGATGCATGCCACCATGCCCAGCTAATTTTT GTATTTTTAGCAGAGATGGGGTTTCACTATATTGGCCAGGCT GGTCTCAAACTCCTGACCTCGTGAATCCACCCACCTTTGGCC TCCCAAAAGTGCCAGAGATTACCAGGCATGAAGCCACTGCAC CTGGGCCTCAAGAANAATTATATATCACGTGGAATAGGGATN 150 IMAGE:564567 AA127577 5′ GTAGTCTCTGCACTGATTTNG AGACTGCACGTGGTTCTTAGAGCCTACAGTGGCTGACAGAGT ATTGGGTATTAACGTTAACGGATCCTGTGATGTGGCGGTGAN TGCAGCTGTGATCCACGAAGTCTCTGAACAGGGCTTAGAAAC TGACTGCACTTTGTTTTTAACAGGAGCCTACGTGAAGAAGAG AGCACACAATTTTAAAAGTTGATTTTATATTCTCTGAGTTTT TCTTCTTGCTTCAACAAAACTCTAGGAAATGCCATAAGCTGA AAGAACATGACCTTCCTCAGACATCTCTTCTCTCCCTTTCCA AACACAACTAGGAGTCATTTTTTTATTGGTGCTATGCCATTA AGAGGTCTTCCTGCTTACGCTTTCCTCAGAGCGGATTGTTGG CTGGGCGCAGTGGCTCAGTGCCTGATATCCCAGCACTTTGGA 151 IMAGE:592125 AA150538 3′ AGGCCG GCATATGACTTGGAATTGGCCTGTACCAAACTCTGGGACCTG CTGTTCCTGGATCCAGTGGTCTTGTTCCAACAGATGAATCTA TAAAATATACCATATACAATAGTACTGGCATTCAGATTGGAG CCTACAATTATATGGAGATTGGTGGGACCGAGTTCATCACTA CTAGACAGCACAAATACGAACTTCAAAGAAGAGCCAAGCTGC CTAAGTACCAAGCTATCTTTGATAATACCACTAGTCTGACCG GATNAACANCTGGACCCAATCAGGGAAAATCTGGGAAAGCAC 152 IMAGE:592125 AA143087 5′ TTGGAAAAACT ATATTATAAAAGCATTTTATTGAACACATTCTGGAGGTAGTT AGAACCAAAACAAAATTTGGGATTGGGGTGGGGATTCTGTTT TGATGATTTAGATTTGGGAAAACTTTGGGTTCTCGTGTCAGC AGGGGCCATGCTGTGGGAAACCTGAAGGCTGATTTGAAGCAG AATATAGAACTGCGGCACGGGAGACCAGGGGCTGGGAATGGG GCTCTCCTGGGAACCAAAGAATGTGGTTCTGCAATTGGCTTG 153 IMAGE:592540 AA160507 3′ GTCTAGACTACTCTCCAGAAAAG CAGCGTCAAATTTGTCTCCACCACCTCCTCCTCCCGGAAGAG CTTCAAGAGCTAAGAACCTGCTGCAAGTCACTGCCTTCCAAG TGCAGCAACCCAGCCCATGGAGATTGCCTCTTCTAGGCAGTT GCTCAAGCCATGTTTTATCCTTTTCTGGAGAGTAGTCTAGAC CAAGCCAATTGCAGAACCACATTCTTTGGTTCCCAGGAGAGC 154 IMAGE:592540 AA160595 5′ CCCATTCCCAGCCCCTGGTCTCCCGTGCCGCAGTTC TTAAAAAAATTTTTTTTATTGAAGAACAGCATACATAAAGAC ACACCAGTTTTAAGTGCACAACCCATTTCTCACAAAGTAGAC ACACTTGAGTTTCCACCACCAGGTGAAGAGATAAAGCCTTAT TAGCACCTCAAAAGATCCTCCCCTTGTGCCCCTTTTCCCATT ACCCACCCTCCTCCCCAAAGGTAACCACTATCCTGACACCAT AGGTTAGTTTTTGCCTGTTTTTAAACTTCACAAAAATGGAAT CATACAGTCTGCATTCTTTAATGTCTGGCTCCTTTCGCTCAA CATCATGTTTGTGAGATTCATCCAGGTTGCCTGTAGCAGCAG 155 IMAGE:60201 T40444 3′ TTCATT TAAGCCCAGCACTTTAGGAGACCAAGGTGGGAGGATCACTTG AGCCCAAGAGTTCAAGACCAGCCTGGGCAGTGTGGCAAGACC CAATCTCTCATTAAATAAATAATAATAACCAAACAAAAAAAT AACCACCACTTTTCACACTCACCATGGCAAAATTTAAAAACC TAACAATTCCAAGTGTTGTCAAGGCTATAGGACAACTGCTGG TGAGAGTGCAAATTGGTATAACCACTGTGAAAAAAAAGTTTG 156 IMAGE:60201 T39159 5′ GCATTATGTATGAAACT AAATTTTGAGTGACTTGAGTCTCTTGCAGTCCCTGATTACAC AGAACCTTTCTGGGCTACTTGGAGCATCACGAATAGTCTTTC CTGTACTTACCAGATTTCAAGTATTCATAACTTGACTCCCTA AGTGTACAAGTTGGGAATAGTACAGGGCCAAGTTCAAGTCGC ATATGCTGTACTGTTCCTCCTGCAAATGTGGGGAAAGAAGAG GGAGATACTAGAGGAACTGAGGCTCCACCCATTCATTCAGTT GCTCTAAGCACCAGAGGACTTGTTTCAGAAAAGGGGAGTGGG AACGCCCTCCGACTTTGCCCTCCTCCGGAGCATCTCTGGGAC GCAGGGAGTCTGGCTAGCGTTAATAGGAAAGGTTGCTCGGCA GAGTGGCCCTGGAGTACTGACTTGTCTCTCCCTCCTTTGTCA AGGTCCATGTTTTTCTGGCTCTTCCTGCACACTCATCCCTAG 157 IMAGE:626199 AA188775 3′ ATTA GACACCAATTCATAGCATTTATTGACATTTCCATTTAAAATG CTAGGAAAGCTGTATNAATTGTAAACATGGAAACCAAATACT TGCATAAATTATTTCAAAAACTCTACAGCACATTAGAAAACA GTGCAGCTATTGAAGGATAGAAACATAAAACCGACAAATAGA AGGGAGGGGCCGATTATTAAATCGTATACCCATACTGAGATT TCAGTGCCTGTTTGAGGACCAGCAAACCATGATTGTCAAGTT TAAGTTGCAGTATTGATGCCACAGTTGGCCTCAATTTGCTCT GCACATTTCGTACATTAACGCTCATAATCTAGGGATGAGTGT GCAGGAAGAGCCAGAAAAACATGGACCTTGACAAAGGAGGGA GAGACAAGTCAGTACTCCAGGGCAGCTCTGCCGAAGCAACCT TTCCTATTAACGCTAGCCAGACTCCCTGCGTCCCAGAGATGC TCCGGAGNGGGGCAAAGTCGAGGGCGTTCCCACTCCCCCTTT 158 IMAGE:626199 AA188785 5′ TCCTGAAACCAAGTCCTN TGAGGATTCATATTGTCATTTTACTTATTTACAGAATCAATA AACCAACACATACACACTATTCAGAGAGGTGGGAAGTGCTCT GCAACCTTCTCCCTCAAACCTGGGCCCAGACCCCAGTCCTGG ACCACTGCATCCACCCAGCAGGAAAGGGGTCCAGCCAAGACT TTTCCTGACTTTGTAACTTACAGACACAAGAGAATAGAGGGT AGAAGGGAAATTCTTGGCACCTGGACTAGAGTGAGATAAAAG GAGAGTAGGAAACCAGTGATAGGAGAGAAGTGAGGGAGGTAC ATACAGTTTTATAAATAACTAGACAAGGTCTGAGCACTTTGG GTGGGGATGGAGTGAGAAAGGCTACAGGCATGTAGGGGCCTA AGTGGAAAAGGAAGAAATAGTGCTTGGGGCCAGAGCGGATGA GAGATCAGCTCTGGGCCTTCTTTTGCCCCATCTGTAAACCAG TGGTTGCCTAGGTGGTGTCAAACAGCCCGTCCCGGTTATCTA 159 IMAGE:681906 AA256172 3′ GG CTCTGGCTATGGGGATAGGAGGAGAGCTCCGGAGGTCTCTGA CCCCTCCCAAGGATCATGCCGCAGCCCCACTGACCCAGGAGT AGGGGCCTAAGGGCAGGGAACCTGGAACTGGGCTGTGTGTTC TGCAAGAAATTGGAGCCGGTGGCACGGCATATGAGGATGCTG GCCTGGAAGGGGACTTCAGAAGCTACGGGGCAGCAGACCACT ATGGGCCTGACCCCACTAAGGCCCGGCCTGCATCCTCATTTG CCCACATCCCCAACTACAGCAACTTCTCCTCTCAGGCCATCA ACCCTGGCTTCCTTGATAGTGGCACCATCAGGGGTGTGTCAG GGATTGGGGTGACCTGTTCATTGCCCTGTATGACTATGAGGC TCGAACTGAGGATGACGTCACCTTCACCAAGGGCGAGAAGTT CCACATCTTGAACAATACCTGAAGTGACTGGTGGGAGGCTCG GTCTCTCAGCTCCGGAAAAACTGGCTGCATTCCCAGCACTAC GTGGCCCCTGTGACTCAACAAGCTGAGAATGGTATTTGGAAA 160 IMAGE:681906 AA256231 5′ ATTGGGA GTTTATTCTACTTTTATTTCACATATATAAAAACAGCTTATA ATTGTACTGAACACAAAATACAAACAAATACATTTTATTGCA CATAAAAATATTTTAAATGAAGTATTGAAGTATTGCACGTAA TAGAATTGATTTAGGAAAGTCACAAACCTATTATAAGACTAG TATTATTCTAGGTCTGAAGATTACAGAATATTTCCTAATAGA GATTTGCCACATCACATATTGCACATTTTCCAACACTATTCT ATGTCTTGCAAATATTCCTCATAGTCTTTGCTTATGTCTTTT CTCTGTAAGACACTGTATAAAAGATTATAAAGGCAAAGAAAT ATGTACCATCGAAAAGGACCTGTCTACAGCTGAGGAAGTAAA 161 IMAGE:704459 AA279755 3′ AAAATAAATACACGATCATCCCATTCTTTTG ACAGCTCTTTGCATCCGGAGAGTGGACAAGAAAATGATGCCA CCAGTCCCCATTTCTCAACACGTCATGAAGGGTCCTTCCAAG TTCCTGTCCTGTGTGCTGTAATGAATGTGGTCTTCATCACCA TTTTAATCATAGCTCTCATTGCCTTATCAGTGGGCCAATACA ATTGTCCAGGCCAATACACATTCTCAATGCCATCAGACAGCC ATGTTTCTTCATGCTCTGAGGACTGGGTTGGCTACCAGAGGA AATGCTACTTTATTTCTACTGTGAAGAGGAGCTGGACTTCAG CCAAAATGCCTGTTCCTGACATTGTGCTAATCCTGCTGCAAT 162 IMAGE:704459 AA279883 5′ GATCCTGAAAAGGGCATTGACTTT TTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTCA ACTGAAGTTCTATTTATTTGTGAGACTGTAAGTTACATGAAGG CAGCAGAATATTGTGCCCCATGCTTCTTTACCCCTCACAATCC TTGCCACAGTGTGGGGCAGTGGATGGGTGCTTAGTAAGTACTT AATAAACTGTGGTGCTTTTTTTGGCCTGTCTTTGGATTGTTAA AAAACAGAGAGGGATGCTTGGATGTAAAACTGAACTTCAGAGC ATGAAAATCACACTGTCTTCTGATATCTGCAGGGACAGAGCAT TGGGGTGGGGGTAAGGTGCACTGTTTGAAAAGTAAACGATAAA ATGTGGATTAAAGTGCCCAGCACAAAGCAGATCCTCAATAAAC 163 IMAGE:712049 AA281635 3′ ATTTCATT CAGACACTGTATCTTTAGATTGATGTCGACCACAAAGTTCAGC CAGAGCTTGAGGCTAGATGCACAGCCTTGCTATTGGGAAGAAG GCCTTTTCTAGCTGTACAACACAGTCTCACTGGGCATTCATCC AGAAATAGAGAAGAAAGTCTGCCAGACTTGAGTTATGTTGTCT TTTATTAGCAGGGAATGTCATCACAGATTGGATAGTACATCCA GGTGCAATGTCACCATCAGCAAGGTCAGCTTGACACTCAAGTG GAAGATTAGGGAAGAATGACTAGGATAAAAAAAAAAGGAGGGC ACCAAGGGAAAGGGATGATGGGGTGAGCTGGCGAGTGTGGGTG 164 IMAGE:712049 AA281696 5′ GGAAATGAAA AAAAAGACAAAGAAACTTTATTTATACAAAACTCCACCCCTTC TGTTCCACTCTCCTCAGCAAACACAGATAACAGGTGATGAAAC TAAAACACACAGACGAGCATTACTCAACCCAAGGTTCCCGCCT TCCCTAGCACCTGAGGTCTGGGCCAACATGCAGGCTAACTGGT GCCTTATGCCTGCTGTCTGGATTGCCCGGCCCACAGGGTGGCT GAGCATATTTATTCTGGGGGTTCCATGCATACGAGGAGCCCCC AGCCATACAGCTGGGCATGGGTGTTTGGCAGCAAATTGTCCC TGCTTTAGTCACAGCAATTTTTCATGTCCTCTGTTTGCTCCC 165 IMAGE:714453 AA293306 3′ CTTAAA CCAGTCCCTGTCCCCTTGTTCACCTTTGGACTGGACAGGGAG CCACCTCGCAGTCCGCAGAGCTCACATCTCCCAAGCAGGCCC CAGACACCTGGGTCTGGAGCAGGGGGAAAAGGTAGAGGACAT GCCAAAGCCCCCACTTCCCCAGGAGCAGGCCACAGACCCCCT TGTGGACAGCCTGGGCAGTGGCATTGTCTACTCAGCCCTTAC CTGCCACCTGTGCGGCCACCTGAAACAGTGTCATGGCCAGGA GGATGGTGGCCAGACCCCTGTCATGGCCAGTCCTTGCTGTGG CTGCTGCTGTGGAGACAGGTCCTCGCCCCCTACAACCCCCCT GGAGGCCCCAGACCCCTCTCCAGGTGGGGTTCCACTGGAGGC CAGTCTGTGTCCGGCCTCCCTGGCACCCTCGGGCATCTCAGG 166 IMAGE:714453 AA292025 5′ AAGAGTAATCCTCATCA CAGATTCTAACAAGAATACTTTTATTATACACGTATCATACA CACAACAATTATTTGGGGAACATTTACAGGCAGAGAGTTCAA TTCCAAATCTCCATTTCACCCACACACACTGTACTGCACACT CACCTTAGGGTTCAGCCCAACAGGAACGAGACAAAGTTATTG CTTTCTGAACAGAGAGTTTCAATTAAATAGAATCTTCCAAGC CAAGAACAGAGCCCAGCATCCTCTTAATTCTTAATACCCTGT ATATATATGAATAAAACCTTATGATGTGTTATAGATTACCCC ATCACCATTAAAAGTTAATATTAAAATTGGATCCCATGTCTC AAAAAAGTCGTAAGAAGTGCACCAGTATTTACAGACCCCATT AAATTACGCATAAATAAAATCTGTACACTCAACGCACTGTTT 167 IMAGE:725680 AA394236 3′ C CCTGATTGTCATAGACAAATCCTACATGAACCCTGGAGACCA GAGTCCAGCTGATTCTAACAAAACCCTGGAGAAAATGGAGAA ACACAGGAAATAAAATTGGAACGAAGAAAGGTTAGGAGAGTA GGGAAGGAACAGGACTGCAAAAATCCTTCTCCACCGCACAGA CTGGGAACCCCTCCTGGCCTGGGGGAAGAGTTTGTTACCTAC CTTACTATTTAAAGAGCCTTCACTGGTTCTGCATCACCCGCC CCTGGACTTCTTAGTTGTTTCTCTAGCGCTGAGCTATCTCCT AACTTTGGACCTATTATCAGAAGGTGACAAGTACTGGCTCTT TATTCATTAAGCTTTTTTTTTTTGAACCCCATTCTTTCCTTC TCTGAAAGTGGTGCTATAAGTTTTAGAATCTTTTAAATACAT 168 IMAGE:725680 AA399334 5′ TCCCTGGGCCAACAGACCCACACACTTAGCCATTGAAATGT TTTTTTTTTGCATTTGTAACATGCACATTTATTCAGAACAAA CAACTCATTAATTTATTCCAAAATAATTTCACTTGATAACTT GAAATACAGAGTAAAACAAATTGGTCAGGTAAATATACATGT AACTTAAAAAGAAACAGTCATGTACTTTAGGCATAAGGACAA TGCTTTTCTCTTTTACAAATTCTTAGTTAGGTCAAATTCTCT GGAAGTCACTACATTTCTTTACTGTGATGTGTTTTGGGTGAA GTTACAACCTATTTGCAAATCACATCACTGGTTTGTCCAAGC AGAGGTAGATGAGAGGTAAGCTCCTCTCCTGCTAAAAGTCTC CTAAAAACAGCAAGAAAATATTTTTATGTGTTCAAAAATGCT CATTTATTTATATTCCTAAATTTTCTTTTACTCAGTATAATA TAGATAATTTAAAAGTAAGTAGAATATTTTTATTATATATGT 169 IMAGE:742904 AA405815 3′ TTTATTTTTATACTTCTAGTTAAAT GGACTCACGGGCGGGGCATGATGGTGGTGGGTACGGGCACCT CGCTGGCGCTCTCCTCCCTCCTGTCCCTGCTGCTCTTTGCTG GGATGCAGATGTACAGCCGTCAGCTGGCCTCCACCGAGTGGC TCACCATCCAGGGCGGCCTGCTTGGTTCGGGTCTCTTCGTGT TCTCGCTCACTGCCTTCAATAATCTGGAGAATCTTGTCTTTG GCAAAGGATTCCAAGCAAAGATCTTCCCTGAGATTCTCCTGT GCCTCCTGTTGGCTCTCTTTGCATCTGGCCTCATCCACCGAG TCTGTGTCACCACCTGCTTCATCTTCTCCATGGTTGGTCTGT ACTACATCAACAAGATCTCCTCCACCCTGTACCAGGCAGCAG CTCCAGTCCTCACACCAGCCAAGGTCACAGGCAAGAGCAAGA 170 IMAGE:742904 AA405814 5′ AGAGAAACTGACCC TTGCAGTGGAGATGGGGTTTCATCATGTTGCCCAGGCTAGTT TTCCTTTCTATATACAGAAAAATTTAAAGTGAATGTGATGTT GGAGAGAGTGGGAAGGAAAAGTAATGGCAAGTATGCTTGCTC ATTACCAGGCACTGTGCTAAGCTCTGTGAATACACAGATAAG TAAAATCCACGCTGTTTCTCAAAGAACTCACAATCTGTTTAA GAAGCAGATGTCTATACAATAATTTTATAACTATTATTCAAT GTGATTAGTACTCACATAGCTCTATATAGAGTGTTATAGAAG AATAAATTAGAGAATATCTCATTTTTCCTCCAGTGGTTTAAA 171 IMAGE:754479 AA410188 3′ AAGATGTCACAGAAACTGAATTGTAAATGGTACGGAAATA GGAGATAAGTTGCCTTGATTCTGACATTTGGCCCAGCCTGTA CTGGTGTGCCGCAATGAGAGTCAATCTCTATTGACAGCCTGC TTCAGATTTTGCTTTTGTTCGTTTTGCCTTCTGTCCTTGGAA CAGTCATATCTCAAGTTCAAAGGCCAAAACCTGAGAAGCGGT GGGCTAAGATAGGTCCTACTGCAAACCACCCCTCCATATTTC CGTACCATTTACAATTCAGTTTCTGTGACATCTTTTTAAACC ACTGGAGGAAAAATGAGATATTCTCTAATTTATTCTTCTATA ACACTCTATATAGAGCTATGTGAGTACTAATCACATTGAATA ATAGTTATAAAATTATTGTATAGACATCTGCTTCTTAAACAG ATTGTGAGTTCTTTGAGAAACAGCGTGGATTTTACTTATCTG 172 IMAGE:754479 AA410567 5′ TGTATTCACAGAGCTTAGC TTTTTTTTTTTATATGTAATGACTGTAGTAACCAGTTTATTA CACAGATTAATCATTCTTGAAAGTACAAGCTCCAGAGGAGAA TCTGGGTCTTTAAATATACACAAGTATTTCCATCAAATGAAT TTTCACCCTTACATCCAAATAGACCTAAGCGGTTAAAAACAT AAGAAAAATAAGAGCTATTAGCTATGTATTAACTGAGAAACC ACATACAAACCAAAGAATATGGAAGAGAGAAAGAAGGGCTGA AAGGCCAAAGGTTGAAGGGGTAGGGAGATGTAAAAGAGTTGG GAACAAAGCCCATCACACTTGATGTACTAATAGCTCCAATCC ATTTAAATGTTGACCAGTTAAACTTAGACCTTAAAATGCAGG 173 IMAGE:773617 AA431869 3′ ATGTGGGTAGAG GAGATTGCTCGGATCTACAAAACAGATAGAGAAAAGTACAAC AGAATAGCTCGGGAATGGACTCAGAAGTATGCGATGTAATTA AAGAAATTATTGGATAACCTCTACAAATAAAGATAGGGGAAC TCTGAAAGAGAAAGTCCTTTTGATTTCCATTTGACTGCTTTC TATGAGCCCACGCCTCATCTTCCCCTGTGCACATGTTTACCT GATACAGCAGTGCTGCGTGTTGTACATACTTGGAACAACAAA CTAGAAATACTGTACTTCTGTACCAACATTGCCTCCTAGCAG AGAAGTGTGTGTGTGACAAGCCAGTTCTACAGGCATTACCTA GGTGTGAGACTAAAAGCTTTTCTTATTGACTTAAATTTGGAT AACAGCAAGGTGTGAGGGGGGTGGTGGGTATGGTGTGTGCTT GGATGGGAAAGAANAGGCTCCACTCACCTATAGGAGATTATT 174 IMAGE:773617 AA431868 5′ TTTAAGTGGAATCC GCGCCGCGCGCCCGAAAGGCTGCGGCCGTGGGCCCGTCCCGC AGACCCTGTGGTTGGGCTGACCCCGCTTCAGGGTGCCGTACA CGAAGACTAGGGCCATCCGGGCAGACTGTAACTTGTTTCTTC AAGGAAGTGTTGCCTTAGAATCCAGATCCACAGTAAGCCTGA GAGTCTTAAAAACTTTTGACTTCAGAATCCTTCCACATGATT 175 IMAGE:781088 AA430002 3′ CAAGAAAAAGTTAAGTCCACTTCACAGGGTGAC GAAAACTGGATATTTGGTCCCCATGGACTTTCTGGTCACCCT GTGAAGTGGACTTAACTTTTTCTTGAATCATGTGGAAGGATT CTGAAGTCAAAAGTTTTTAAGACTCTCAGGCTTACTGTGGAT CTGGATTCTAAGGCAACACTTCCTTGAAGAAACAAGCTTACA GCTCTGCCCGGATGGCCCTAGTCTTCGTGTACGGCACCCTGA AGCGGGGTCAGCCCAACCACAGGGTCCTGCGGGACGGCGCCC 176 IMAGE:781088 AA430230 5′ ACGGCTCCGCAGCCTTTCGGG TTTGCCCAGCAAAGACAAATATATTTGTCCCTGTTGCTACAA TAGGAAGTTAACAATCTGGCAAGATATCTGAACACAAGCAAA TGAAAACAGTTCACCTAACACCCATGCAAATTATAAATTTCC TCCCATATACAAAATGATGAGAAATAACAGCAAAAATGTATA CTTTCTTATTTTTGAACTTTTAAAGTTCTAGTTTGGTCTTTG AATCAAAACAAAGTAAAAGATGTTTATAAAAGCCATTTCCTT TTCTTTCCCCACTATGCTCATTTGACTTGCTCTTCCCCCTAT AGGGTACCCTGAGTCATTCAGAGAAGGAGAATTAATAGCACT GAGTTGGTGATGAAGCTCCTGTTAGGACATATGGCTTCACAA AAAGAAATACTTCCAGATAAGTCAGAGAGACAGTTGGACGTC TTGAGCAAATCTTGAAAGAGATAGGGAAGAAAGCAGAAGTTG 177 IMAGE:782141 AA431190 3′ TTGGGTGGT GTGCTCCCACTTTGACAATGATGAAATTAAAAGGCTGGGCAG GAGGTTTAAGAAGTTGGACTTGGACAAATCAGGGTCTCTGAG CGTGGAGGAGTTCATGTCCCTGCCGGAGCTGCGCCACAACCC GTTGGTGCGGCGAGTGATCGACGTCTTCGACACCGACGGTGA TGGAGAAGTGGACTTCAAGGAATTCATCCCGGGGACCTCCCA GTTCAGCGTCAAGGGCGACGAGGAGCAGAAGTTGAGGTTTGC GTTCAGCATTTACGACATGGATAAAGATGGCTACATTTCCAA CGGGGAGCTCTTCCAGGTGCTGAAGATGATGGTGGGCAACAA 178 IMAGE:782141 AA431516 5′ CCTGA TTTTGCAGTTACAACATTTACCACTTTATTATAAAGGCTACA ACTCAGAAACAGCCAAATGGAAGACATGTATAGGACAAAGAA AGATGTGGGGGTGGAAGAGGTTGTATGGAGCCTCCATGCCCT CTCTGGATGCCATTGGTTGACTGGGGGAATTAATTCCCTGGT GCTTCCAGCCTGCAAGATGAGCTCCTTCAACCAGCAAGTCCC CAGTCAAAAGAGTGCACGGGGTGTAGCTGGAAGTTGAGCAGA TGGTAGTTTGCATGGATGAGATAAAGCCCCAGGGGACAGGGC AGCTACACATGAATCCAAATAGTCTAATCTCCAAAAGGAACA GAGAGTGGATTCATACAACATACCAAGCCCGCCCCCTAAATG CATCCCACTCAGGTCACTTATAAAGCTCCAAGGATGGGCCAA GAACACAAGCTCTACACCAGGGAAACTTGGAGGCATCAGAAG GACAGAATAAGACCCAGGTTCATAGGGGATGAAAAATCGAAC 179 IMAGE:782758 AA448002 3′ AG CAACAATAGCGGGAATGAAGACTGTGCGGAATTTAGTGGCAG TGGCTGGAACGACAATCGATGTGACGTTGACAATTACTGGAT CTGCAAAAAGCCCGCAGCCTGCTTCAGAGACGAATAGTAGTT TCCCTGCTAGCCTCAGCCTCCATTGTGGTATAGCAGAACTTC ACCCACTTGTAAGCCAGCGCTTCTTCTCTCCATCCTTGGACC TTCACAAATGCCCTGAGACGGTTCTCTGTTCGATTTTTCATC CCCTATGAACCTGGGTCTTATTCTGTCCTTCTGATGCCTCCA AGTTTCCCTGGTGTAGAGCTTGTGTTCTTGGCCCATCCTTGG AGCTTTATAAGTGACCTGAGTGGGATGCATTTAGGGGGCGGG 180 IMAGE:782758 AA448145 5′ CTTGGTATGTTGTATGAATCCACTCTCTGTGCC TTTTATTATTAAATGTATATTTTTAATAAAGCCAATAGTTAT TTTACTTATAGGAGCTTTAAAAGATACAAAATGTAGAGTTCC AGTTTGGAAGCATTGTAACTATACACACAATGTCCTGCTGAT GCCCTAGCAAGGCACCCACGCCCAACCATGCAAAGGACACAC ACGTTCACACATGCACACACATGCGCTTTGGCGAGACCCCTC 181 IMAGE:784104 AA432052 3′ TGCCAAGCGCACACCCTGGAAT GGACTTAGAAGCCTTACAAATACATCTGTGCATTCTTGCTTC AGACTTTACAACTGAGGGCCAGCCCAGTCTGGAAGCATCTCT TATTAATGTTACAAGGAAACCGCTACCTCAGCAAACAAAAGG AATGGAGGAGGAGACTTACAACTGTTTTGTATATAGACATTT 182 IMAGE:784104 AA446737 5′ TCAGGCACGTGCTTT TTTTTTTTTTTCTGCTTCAATATAATTTTATTAGCAGTTATT ACATCAAAATTCACATTTAGAGGATCCAGAGGACTGTCTTAG AAAATTCTAAAGCATATTTAATTAGGTTTTAACAGTAAGGGA GAACTTAATATAACACAGCCCTTAAAAAGTCAAGACTACTAC TGAAAATTAAGTGCAGTTCTATCAAGAACTAGAAATGAACTG CACGTGTAGTGTCACTTAAAGCAAAGCTTCATGAAAATATAA TACACTTCTATGAATGTATCAGTGGCAAACATCATTGGCTTC CAAAAAACTGACACTAAAGGAATTTCCAATCAAAACACAAGC ACAGTGGCTTTCATTCAATATAGAGCTATGATAAGTCTATCA AGAGACCCTGAATCCTTACGTACTTGTAATATGATTTTATGC 183 IMAGE:784218 AA446867 3′ TGTGACACT TTTTTTTTTCACTCAATAAATTTTTATTAGAAATGCAGTTAC ACTGAGAAAGGATTTCACAATGGTCAAATCAGTGCACAATAC TACCTAGTTTTATACACTGAAAAAAATGTCTTGTCAGGCTAC ATCATTTTAGAAGACACTTTACAGCATTCTTGTAGCATTAGA AATAATGAATAGAAGAGCGTCAAGGTGAAAACAAACACCAAA TTTGGTCCAATAATACTGATTGCTCTTTGTTAAAATTCCTTT GATACAGGTACTTTTTATAAATGAATATGAATGAACATTCGG 184 IMAGE:784910 AA447632 3′ TTAAAATGACTTACTTGA GGGTGACACCAGGCTTACCTTTTAAAGTTTAGTATACGGAGA CAATTTTAATGGAAATAACTACTGTAGACTATTGAAGAATGA TCTCTTTGTGATTTAAGAAGTGGCTGGATTGGAACTTTTAAT ATGCTAATGTGGAAAATTAATTACCTTTATGAAGGTGGTTTA TTACAAATAAGCACACTAACCCCTCGGAAGTTGTTTTACCTA CTTTAAAAGTTTTAATGGATTGCACCTCTGTAAACTATTCCT 185 IMAGE:784910 AA448033 5′ AAAATGTGTATGATATATTTGAAAAGGCTTCCATTA TTTTTTTTTAACTGTCCGCAAGTTAAAAAGATTTATTGCTAT TCCAGGCTTCAAATGAGCCCAGAACTCAGGGCTGGTGTGTGT TTCAGAAGTTGTTATGATGTAACAGGGTGGTAGAAAAATCCA GGCAGTTTGATGTCGAGGCCACCCTCTCTTCCTTGGACCCCT GCTCCAAAAGCAGCTGCTGGTGAGGCTCTTTCCCATCTGCCT CATTCACCCAACAGGACTCCAAGACTGAGGCAGGCAGCCTTG TGATCCCCACAGCTCACAGGTGAGAGGCTGCTCATACCTCTC CTAGCACTGGAAGAGCCTTGTCCTTGGGACCGGACACTATGG CTTTGGCCCTGTGGAGGGAGAAACGGTGCCACAGGAGTTGTC TTAAGAGGACAAGGCATGCACGGTCTGAGATCAGAGGTTGTG ACGTGGCCACCCATGAGCCAGTCCGTTTGGGACACATCACAC TGCACAGCTTTTTAAAAAATAATTAGGCTGCAATCTTTTAAA 186 IMAGE:795173 AA453471 3′ ATGGTAAGATTTCATATACCAATC AAAAAGCTGTGCAGTGTGATGTGTCCCAAACGGACTGGCTCA TGGGTGGCCACGTCACAACCTCTGATCTCAGACCGTGCATGC CTTGTCCTCTTAAGACAACTCCTGTGGCACCGTTTCTCCCTC CACAGGGCCAAAGCCATAGTGTCCGGTCCCAAGGACAAGGCT CTTCCAGTGCTAGGAGAGGTATGAGCAGCCTCTCACCTGTGA GCTGTGGGGATCACAAGGCTGCCTGCCTCAGTCTTGGAGTCC TGTTGGGTGAATGAGGCAGATGGGAAAGAGCCTCACCAGCAG CTGCTTTTGGAGCAGGGGTCCCAGGAAGAGAGGGTGGGCTCG ACATCAAACTGCCTGGATTTTTCTACCACCCTGTTACATCAT AACAACTTCTGAAACACACACCAGCCCTGAGTTCTGGGCTCA TTTGAAGCCTGGAATAGCAATAAACCTTTTTAGATTGCGGGC 187 IMAGE:795173 AA453978 5′ AGTT TTTTTTTTTTTTTTTTTTTTTTTGGCTTTCTGGGTCTTTTAT TTGTACCCATGTGTCTGTCACACCATGAATGTACCTGGGGAA ATCAACTGACCTCCCTGAACATTTCACGCAGTCAGGGAACAG GTGAGGAAAGAAATAAATAAGTGATTCTAATGCTGCCTAGGT CACTCTCAACCCCCATTTACTGGCACAGTTGGGTGGAGAGAA GGGAAGGGGTATGATTGTCCTGATGGCTCAGGGATAGAGGGC ATGGTAGAAAGCAAAGTACCCACACAGGCCCCAGTTCCAGCT GCGGAGGACACTTGGGCGCTCCAGGGACAGGACTTGCTGGTA CACAGTCTGCCCTTCCCGACGCAGGCACACTGTGAATTGGTC 188 IMAGE:796297 AA461304 3′ AGCGATGACTGTCCGGTGCTGATACATTC GAAACACCAGCTCATTTAAGCTTTCCCCAACGCCCGGCCCTC CGGACGAGTACCTAACAACCACCGGCGCCCGCATCTGGAATA GGCTGGCGAGATACTTAGTATCCGAGGGCTCGGGACTTGGCG CCATCGAGGTCATGGGGACCCAGGATCCAGGGAACATGGGAA CCGGCGTCCCAGCCTCGGAGCAGATAAGCTGTCCAAAGAGGA TCACAAGTTTATTGCCCTGAAGAGACTGGCGGCACCAAGGAT GTGCAGGTTACAGACTGTAAGAGTCCCGAAGACAGCCGACCC CCAAAAGAGACGGACTGCTGCAATCCGGAGGACTCTGGGCAG CTGATGGTTTCCTATGAGGGTAAAGCTATGGGCTACCAGGTG 189 IMAGE:796297 AA459721 5′ CCTCCC TTTATTTNNTTGAATCTATTTAATTGCTCAGACTGTGCTAGA GAATACGTACCATGAAATACATATATTTCATAAGGTTCAGTT ACAAAATGGATTGTTTCAAATGGCAATTTCTTACACTAACCT GATTATGAAAAAAAGAAGTCTGTATCATCTGCTTCCAAGTCT GTTATGTCCAAATATATTTTAATTATGCATTTATTTTGCTAC TTTTATAAATATTAGAGATTTCACCNTAAATTATTTTTGTAA CTAGTTCTAGAACATGTTTNCCAATTATTATTNNCCTAATGG GAGACATATAATTGACCNATGGTTTATGGCATATATGGTCCT CTACACAGNGGAACCTNTTTTTAAAAGGAATAGGTAAAGGAA 190 IMAGE:80948 T70057 3′ AATGCGGGACGGCCTGGGCTCTCCAGGGCCAAGGGCCA TTGCTCCAGTTTTTCAGAAGAAGTGAAGTCAAGATGAAGAAC CATTTGCTTTTCTGGGGAGTCCTGGCGGTTTTTATTAAGGCT GTTCATGTGAAAGCCCAAGAAGATGAAAGGATTGTTCTTGTT GACAACAAATGTAAGTNTGCCCGGATTACTTCCAGGATCATC CGTTCTTCCGAAGATCCTAATGAGGACATTNTGGAGAGAAAC ATCCGAATTATTGTTCCTCTGAACAACAGGGAGAATATCTCT GATCCCACCTCACCATTGAGGAACCAGATTTGTGTACCATTT GTCTGACCTCTGTAAAAAATGTGGATCCTACAGAAGTGGGAG CTGGGATAATCAGNTAGTTTACTGCTTACCCAGNGGCAATAT CTGTGGATGGAGGNCAGTGCTACAGAGACCTGCTTACACTTT 191 IMAGE:80948 T70123 5′ TGGAC GCAACTTGAATTGTATTTTTTATTGAAAAGAATTCAGGCTAG AGTTGGGAGGAGGATGCAAGAGCTACTGGGAAGGGGGAGCTC AGTCTGAACCTGGGGGATCAGGGGAGTAGGGGACTCTCCCCT TGTCCACTGATGGGGGGTCTGGCTGTTACTCCTCTCCCTTCA GCACAGAAAGAACTTGGTCAGTAAAAATGCCTGTGTAAGTGC TCATGGCTGCTGTGCTTTTGCTGTACAAGTCCCTGAGTTTCT CATCTACAGCGGGCAGGTATGTCTTCTCGTACAGGTTCTGGG CGGCTGTCTTTGCTGACTCCCAGTAACTGGAGAGAGATTCCT 192 IMAGE:809523 AA454580 3′ TCACCTGGGTGAGGAAGGTCGGGC AATTTGAGGTCCAGGGGACCGAACAGCCCCAGCAAGATGAGA TGCCTAGCCCGACCTTCCTCACCCAGGTGAAGGAATCTCTCT CCAGTTACTGGGAGTCAGCAAAGACAGCCGCCCAGAACCTGT ACGAGAAGACATACCTGCCCGCTGTAGATGAGAAACTCAGGG ACTTGTACAGCAAAAGCACAGCAGCCATGAGCACTTACACAG GCATTTTTACTGACCAAGTTCTTTCTGTGCTGAAGGGAGAGG AGTAACAGCCAGACCCCCCATCAGTGGACAAGGGGAGAGTCC CCTACTCCCCTGATCCCCCAGGTTCAGACTGAGCTCCCCCTT 193 IMAGE:809523 AA456474 5′ CCCAGTAGCT ACTGCTCTTTTATTCAATGGAACATCCCCGCTTTAGCCAGTG TTGAATCTAACACCGAAAAAAGCCCAGAGAAATTTCTGCAGA TAAACCAGTGAAGAGAACGCGCAGTATACATTATTGTCAACA GAATCACTTCATGGAGAGGGAAGCGGGAGGAAAAAGGAAGGA GAATGAACAAGGGGCTCAAACCCCTACACACTGCAAAACATT 194 IMAGE:809648 AA454673 3′ CAGACATTTGGGATTAAAAC CATATGAAATTCTAATAAATCCATTTTATTTGTGGCACCACA ATATTATCATTAAGCTCTCTTTTTACACAGTCTGCAATTTGT ATCAGCTGCCCCAGTGTGACTCTGCCCTTATTTTAGGAACAA CCTTTTGCTGGGTGGCGTCCTAGAAGGTCTGGGCCTGGGCAG CAGCGACTGGGAAGCCCACCTGTGCTTTCCCCCATCTGGGTG GGGCGGCACAGAGACCCTGAGAATCAGCGGTTATGGGAGCTG TGTGTTAGCTGTGTGTTATTGGCTTTGGCTTCAGCATGTCCT GCCTAGGAGTCTCCAGCAGCTGTGGTTTCCTTGGACTGGAGG CTTTTTCTCCTGATGACAATCGTGACAGGTCCATCAGGCAGT GCGTTGATGATGTTCCAGGCTTCAAACCGTGTGAGGCCCTGC ATGGCAGTGCCACCCAGCTGCAAGATTTCATCTCCAGGCTGG ACTGTCTCACTTTGTTCTGAGGCTGCTCCTTTGAAAATCCTG TTAATGGTGAGAAGCTTGTCTCCGTGTAGGGAGCCCTTCCCT CCTTCCAGGCTGTAGCCCAGCCCTGCCGACATCTTCTCCATG 195 IMAGE:809776 AA454732 3′ GTCACCGTGAAGACTGTGGCCTC GCACAGGGCTGGCTCTGTGCAGGCTCCAATCTAGGACACAAT TATCTTTAATCTTTGTTGGCCTAAAAATCCTCTAGCATTGAC TAACCGGTTCAATCCTCCTCCAGCAAGTATGTGGACTGGACT TGTGTGATTTCTGGTCCTGACTTCCTTTGGTTTGCTCAGGTT CACAGAGTGTTTCCAAATGGGCTGGCCTCCCAGGAAGGGACT ATTCAGAAGGGCAATGAGGTTCTTTCCATCAACGGCAAGTCT CTCAAGGGGACCACGCACCATGATGCCTTGGCATCCTCCGCC AAGCTCGAGAGCCCAGGCAAGCTGTGATTGTCACAAGGAAGC TGACTCCAGAGGCCATGCCGACCTCAACTCCTCCACTGACTC TGCAGCCTCAGCCTCTGCAGCCAGTGATGTTTCTGTAGAATC TACAGAGGCCACAGTCTGCACGGTGACACTGGAGAAGATGTC 196 IMAGE:809776 AA454784 5′ GGCAGGGCTGGGCTTCAGCATGGAAGGAGGGAAGGGCTCC CGCGGAGAAAAAAGTTCTCGCCACCAAAGTCCTTGGCACTGT CAAATGGTTCAACGTCAGAAATGGATATGGATTTATAAATCG AAATGACACCAAAGAAGATGTATTTGTACATCAGACTGCCAT CAAGAAGAATAACCCACGGAAATATCTGCGCAGTGTAGGAGA TGGAGAAACTGTAGAGTTTGATGTGGTTGAAGGAGAGAAGGG TGCAGAAGCTGCCAATGTGACTGGCCCGGATGGAGTTCCTGT GGAAGGGAGTCGTTACGCTGCAGATCGGCGCCGTTACAGACG TGGCTACTATGGAAGGCGCCGTGGCCCTCCCCGGAATGCTGG TGAGATTGGAGAGATGAAGGATGGAGTCCCAGAGGGAGCACA 197 IMAGE:810057 AA455300 3′ ACTTCAGGGACCGGTTCATCGAAATCCAACTTAC TTTTTCTTTTAAATCATGACACTTGGTAGGTTTACCACCAGC ATCCAAAATGAACAAAAACGGAAAAAAAAGCATTTACTATAT ATTTCAGATTTCTTTGGTTGGGGTTCTCCCCATGTGGTATTA ATATTTCTTGTTTCAATATATATATTACCAAAACAGTAAAAA CCAGGAAAAAAAATAGAAACCTAGCGGTTGCTGAAACTAGAG AGGCTACTCTCTTGTCTTCCGTGCAGGAATTCCCAGGTTCTC AGCTTGCTGGAAAAATTTGTTGACATTTTCTTTTTGTAGCTG TTTCTTAAAGAATAACAGTAAACATTCCAATGTCCAAATCTT GGTTAGTCTTCCACTTTATTGCTTGGATGTTTCTTTGGTGTT GGTTAAGGTTGTGGCCTGCTTTTTGCTTTATTTCTGAATGGT CATTAATTCTTTAGGTCACCTGCCGATGGTGAAGGTGCCTGA GGAGCCTGGTGTTACTCAGCACTGCTCTGCTGGGTGGGTGGA 198 IMAGE:810057 AA465019 5′ GCAGGGTTCTCAGTTGGTGCTTCACCTGCC AGAGGAGCGGAGCGGGCAGCGGGAAGGGGCGCGCTCCGCTGG CCGCCGAGCCGCACTTGTCCAACGTGGAAAACCCAAATACCA GTTTCAAACACTTGGGAAACATTCAGCCCCGCTGCGCAGCGC GCATGCGCCCCGGCCCCCTCCCCCGGCAACGGCCCCGCCCCC CGCCGCATTCACGCCCCTCACCGTCCCAGGCCCTGGGGGCTG CGGGCTCGAGGCCGGCCCTCGCGGNGGCGTGGCCTTGCCTGT CACTTTTTCCAGAGGCGAGGGTCGCGGAGGGGACAGCGTCAG GGCCGCTGGGGTGTGGACGGCGGGCGAGGCGCAAACTTTACT AGGAGTTTTTGGCACTTGGAGGCAGAGCCTGTTGGGCGGCAC AGCACGCCCGCTGGGAAACGCAGGGGAGCGGCCTGCTTCGCT 199 IMAGE:810061 AI732774 3′ GAAAACCCGACCAGGACCTAACGGGCCGCGGGACA GGCTGCGGTAGTTGCTGTGTACCATGGTCTCGGAGGTTTCTG TCCCGCGGCCCGTTAGGTCCTGGTCGGGTTTTCAGCGAAGCA GGCCGCTCCCCTGCGTTTCCCAGCGGGCGTGCTGTGCCGCCC AACAGGCTCTGCCTCCAAGTGCCAAAAACTCCTAGTAAAGTT TGCGCCTCGCCCGCCGTCCACACCCCAGCGGNCCTGACGCTG TCCCCTCCGCGACCCTCGCCTCTGGAAAAAGTGACAGGCAAG GCCACGCCCCCGCGAGGGCCGGCCTCGAGCCCGCAGCCCCCA GGGCCTGGGACGGTGAGGGGCGTGAATGCGGCGGGGGGCGGG GCCCGTGCCGGGGGAGGGGGCCGGGGCGCATGCGCGCTGCGC AGCGGGGCTGAATGTTTCCCAAGTGTTTGAAACTGGTATTTG GGTTTTCCACGTTGGACAAGTGCGGCTCGGCGGCCAGCGGAG 200 IMAGE:810061 AI734162 5′ CGCGCCCCTTCCCGCT TCCTCGTCCTCCTCGGGGGCCTACCGAGCGGCTACGGCGCTC ACTGACCGCGTCCGTACGGCATGCTGGCGGGCAACGAGAAGC TAACCATGCAGAACCTCAACGACCGCCTGGCCTCCTACCTGG ACAAGGTGCGCGCCCTGGAGGGCACAACGCGAGCATAGAGGT GAAGATCCGCGACTGGTACCAGAAGCAGGGGCCTGGGCTCAC CGCGATCTACAGCCACTACTACACGACCATCCAGGACCTGCG GGACAAGATTCTTGGTGCCACCATTGAGAACTCCAGGATTGT CCTGCAGATCGACAATGCCCGTCTGGCTGCAGATGACTTCCG AACCAAGTTTGAGACGGAACAGGCTCTGCGCAATGAGCGTGG AGGCCGACATCAACGGCATGCGCAGGGTGCTGGATGAGCTGA CCCTGGCCAGGACCGACCTGGAGATGCAGATCGAAGGCCTGA AGGAAGAGCTGGCCTACCTGAAGAAGAACCATGAGGAGGAAA TCAGTACGCTGAGGAGGCCAGTGGGAGAGCAGGTCAGTGTGG AGGTAGATTCGCTCCGGCACGATCTCGCCANATCCTGAGTGA 201 IMAGE:810131 AA464250 3′ CATGCACGCAATATGAGGTCTGGCCAGCAGA CTGAAAGGGTGCGCCGAGTCAGATAACCTCGGACCTGCTCAT CTGGAGCTGCTCCGTGTGGCCAGCGACCTCCCGGTTCAATTC TTCAGTCCGGCTGGTGAACCAGGCTTCACATCCTTCCGGTTC TGCTCGGCCATGACCTCATATTGGCTTCGATGTCACTCAGGA TCTTGGCGAGATCGGTGCCCGGAGCGGAATCCACCTCCACAC TGACCTGGCCTCCCACTTGGCCCCTCAGCGTACTGATTTCCT CCTCATGGTTCTTCTTCAGGTAGGCCAGCTCTTCCTTCAGGC CTTCGATCTGCATCTCCAGGTCGGTCCTGGCCAGGGTCAGCT CATCCAGCACCCTGCGCAGGCCGTTGATGTCGGCTCCACGCT CATGGCAGAGCTGTTCCGTCTCAAACTTGGTTCGGAAGTCAT CTGCAGCCAGACGGGCATTGTCGATCTGCAGGACAATCCTGG AGTTCTCAATGGTGGCACCAGAATCTTGTCCCGCAGTCCTGG 202 IMAGE:810131 AA464358 5′ ATGGTCGTGTAGTAGTGGCTGTAG ATAATTTGCCAAGATAAATCACTTTTATCTCTATAGGAAAGG GAGGATCTAAAAAAAATATAAATTACATTAGTAACACAACAT AAGAAAAAGACAGGGACAAAAACAACAGAGAAGTCTGAATGA TGCTACCCTAACCTATTTATAAAAAGGCCCTGCATCAGAAAT TCACAATCCTACCCACTTCTAAAAATATATTTAGACATGTAC AGAAGCGGTGGGCTTGTTTTTAAATTGTTTGCTTTATTTGTA AAAATATATTAAAGGTGAATAGAAATCCTCTCTCCCTTCCCC CTGTCCAGCCCCCAGCTAGGGACTGGAGATCAGGGGTAACTA 203 IMAGE:810621 AA464744 3′ T CTTTTAGCTGGCTACACATGAGGCCACTTGTTTTAGGGTGAG CTCCAGGGATTTGCCTGGATTTTGAAATCATGTAGAACATTA TCCACGTGGCTGTGGCTGTGGCTGTGGCTGGGCCCTGGCAGG TGGAAAACCATCTCCCAGAAACCTGAAATCACCTGCCAATGA CGCAGATAACCCTGGCCCTACAGCCTGCTTGCTCCGCCTATA CCACAGAGCACAGCCTGGACATTATGGAGGGTGTGGCGGGAC GGCCACACCTGGGTCCTCCATCGGGAACTTTTCATGCTTCTT TCTCCACCTGAGGTCTTGGTCTGAAGAAGACCTCAGGACTCA 204 IMAGE:810621 AA464036 5′ CATCTT GCAATCATAAAATAACTTTATTGGTCAGGTTAGCCACCACTC ATGCTTTTCCTGTAATAAGGATCCTTTATAAAGGCATGATGG TGTTCACATGCAGATGCTTTCTGAAGAGCCCTGGGGCAGGGG GCAGCCTTGCCCCTCACATCGGAGCTCCTTTGTTGAAATGAG CTGGTTTGGCTTTTGTGGATTCCAGGTCTGGAGCCAAGAACG TAGTCCAAAGATCCCCTCTTCCCTTCTCAGGGAAGGTGCTTC AAAGCATACACAGTATCAGGGATGTGATGGCATCTGGGCAGA GCTATACTTGGGCTAACTCTCCTCCAACAGTCCTTGCCCCTG ACTGCCCAGATGGCTTTGTCCCAACCTTGCCCAAAGGACGGT 205 IMAGE:811162 AA485748 3′ GGGTTAAGCCCAGGCAACATT AATGTATAGGGCTATATTTTGGCAGCTGGGTAGCTCTTTGAA GGTGGATAAGACTTCAGAAGAGGAAAGGCCAGACTTTGCTTA CCATCAGCATCTGCAATGGGCCAAACACACCTCAAATTGGCT GAGTTGAGAAAGCAGCCCCAGTAGTTCCATTCTTGCCCAGCA CTTTCTGCATTCCAAACAGCATCCTACCTGGGTTTTTATCCA CAAAGGTAGCGGCCACATGGTTTTTAAAGTATGAGAAACACA GTTTGTCCTCTCCTGTTATCCAAGCAGGAAGATTCTATATCC TGATGGTAGAGACAGACTCCAGGCAGCCCTGGACTTGCTAGC CCAAAGAAGGAGGATGTGGTTAATCTGTTTCACCTGGTTTGT CCTAAGGCCATAGTTAAAAAGTACCAGCTCTGGCTGTGGTCC 206 IMAGE:811162 AA486471 5′ GTGAAGCCCAGGCCAGG TTAGAGCTTAATGGAATTTTATTTTGAAAATATGGCAAGAGT CTAAGGCACTTCAAACATTTAAATACATAGAGGACCAAAGTA AATGTGACACGGTAAAAAGGAATCCATAAATACAAAGAGAAC ACTGTGTTTCTCTAGAGGCAAATACAGAGCCGATTCCTCTAA CACAATCCAACCTTTAGCATTGGAGTTGTGCAATTAATACAA ATGATGATGTTACGTGTAGTTCTTCATGGCTTTAGTATGGAA TACAAAAGCTGAAAATACTGTGTCAAGTTCATATAGATACCC TTTTTATAAAAAGTCATATATTACATCTACCTAGTTAAGACC 207 IMAGE:812975 AA464605 3′ AAATGAGAATATTCTTTTGTAAGT CTGTGTCCTAATTTATTATGACTACATAGCCCACATTCCTCT GCCCACGCATCCGTGGAGTCCAGAGCCCAGAAAGCCTCCTGC TGCCCTGCCAGACCGTTGAGCTCCTCAAGAGCGAAGTGTGGC ACAGGCTGATCAGCTCATGCAGAATGGCAGGGCTTCAGCTGC CCAAGTGTGTGCGTACCAGAGCACAGCATTCATGAAGCTGTC TGACTCCACCTCCACCTCTGATAATGCGTGGGTGCTTTTGGG ATAGAGCAGGAGCCGAACAGGCACATTCCGGGTCTTGAGGGC ACGGTAATACTCCATGCCCTGCTTGAAGGGCACACGCCGGTC CTCCTGGCCCAACATCAGTAACAGTGGTGTCTTCACCTGAGG 208 IMAGE:813279 AA455941 3′ GATGTATC TTCCCAGCCATGCTTTGCAAGATGGGCTTTGCGGTACATACT AGTGAACTATCGTGAATCCACGGGCTTTGGCCAGGACAGCAT CCTCACCCTCCCAGGCAATGTGGGACACCAGGATGAGAAGGA TGTCCAGTTTGCAGTGGAACAAGGAGCACCAGGAGGAACACA TTGATGCAAGCCATGTGGACCTTATGGGTGGATCCCATGGTG GCATCAATACCAGCCACATGATTGGTCAGTAACCAGAGACCT NCAGGGCCTGAGTGGCACGAGAACCCGTGATAAACATAGCCA CCATGTAGGGCACCACTGACATCCCTGACTGGTAAGAGGTGG 209 IMAGE:813279 AA456408 5′ AGGCTGG TTTTTTAGTTAAATACGCACAATTTTATTGATTGAAGAGATT AGGACAAAAACATTAAACCAAATACAGGACAAAGCACCAGAG GCCATAGATCCCCACCATGCATGTCACCAACCTCTCCTCCTC CAAGGTACTTAAAAAATTGGGGAGAGGGGAAAAAAAAGGTCC TTCTTGACACAGCACCATCTTCAGAATGTTAAAAAAAAAAAA AACCTTCTCTCCTTTCTATCTTCCATTAGCAAAATAGAATCA AGGGCAAATCCATGGCCGCCTTGTCTCCTGGTTACGAAGGGT GAAGCCGCCCTCCTGGGAACGTGAGGACAGGGCTCCTGCTGC GCAGGCATAAAGCATCCAAGAGTCTGCACATACATGCCACAC 210 IMAGE:813426 AA458653 3′ ACTATTATGA AAGAGAGAGGCAATTTTATTCTTCCAAAAAAATGCACCAAGA GAGGGTGAGCACAGGAGCACCCCTGGCCACATCCCCCATCCT AAGCAGGGTCTGAGATGAGGCCAGGCCTGACGTGGGCTTGGG AGAAGCTGACGGAGCTCCCTGTGGCCTTGGGGAGGGAACCAG GCAGACCTGGAAGTGGAACTTTGTTGTTAGCACCAGGAGCCG CCCACAGCTGGGCTCGGCAACAGGGCAGCACATGGCCCTGTT GCTGCCACCTGAGAGTCTGGGGAGGGGCTGGTGGCAGAAGGC TCCCTGCAGGAGGTCACCTGAATGACTCTCAGATTCACAGAC CCCCTCTGCCCCCACAACCCCTGTAAACATGAGAATGGGCTC GTGACACCCTCAACACCTCAGGACAAGATGAGGGTCCGAGAT GTGTGGCTGGGCTTCAGGCGGCCCAGGAGCTGCCGGGCTTTC TCCTGCATGAAAAGCTGGTCCCTGGTCCCCCCGCAGGCCACC GTCTTCCAGGCACTGGACATAGGGGCAGGTGTCGTGAAGTGG CTTCGGGGCTTCTGGGCCACTGCTGCCTTCTCGGGCTTGGCT 211 IMAGE:815526 AA457034 3′ GCAAGAA ATTCGGAACACCGGACGCAATCAAGAAAGTCCGGAAGTCTCT GGCTCTTGACATTGTGGATGAGGATATGAAGCTGATGATGTC CACACTGCCCAAGTCTCTATCCTTGCCGACAACTGCCCCTTC AAACTCTTCCAGCCTCACCCTGTCAGGTATCAAAGAAGACAA CAGCTTGCTCAACCAGGGCTTCTTGCAGGCCAAGCCCGAGAA GGCAGCAGTGGCCCAGAAGCCCCGAAGCCACTTCACGACACC TGCCCCTATGTCCAGTGCCTGGAAGACGGTGGCCTGCGGGGN GGACCAGGNNGACCAGCTTTTCATGCAGGAGAAAGCCCGGCA GCTCCTGGGGCCGCCCTGAAGCCCANGCCACACATTCTCGGG ACCCTCATCTTGGTCCTGGAGAGTGTTGGAGGGGGTGTCACG 212 IMAGE:815526 AA456878 5′ AGCCCATTTCTCATGGTTTTACAGGGGTTG GAAAGAAAGAGTGGAGGGGTTAACATGGGGCCCACCTCACAA CCCACTCTTCACCCCCAAAATCACGCAGGGATGGGACTCAGG AAAGGGAAGCATGTGTGTGTTGAATAGGAGCCCTAACTGTAG TTACTTCTTTCACAGCAGGGAAGGAAGAGGGAAGAGGCAGCT GTGGAGAGGATGAGGTTGAGGGAGGTGGGGTATCTCGCTGCT CTGACCTTAGGTAGAGTCCTCCACAGAAGCATCAAAGTGGAC TGGCACATATGGGCTCCCTTCACAGGCCACAATGATGTGTCT CTCCTTCGGGCTGGTCCGGTATGCACAGTTGGGGTACCTGGA GCCGTTTGTCAGGCGGCAGTCTGTGATGTGCATGCTGGAGTT 213 IMAGE:840493 AA485893 3′ GCTCTTGTAGCAGTTGCCCTGCCCGTTCTT CCTGGTAGATGTCCAGAATGTCTGTTTCCAGGAAAAGGTCAC CTGCAAGAACGGGCAGGGCAACTGCTACAAGAGCAACTCCAG CATGCACATCACAGACTGCCGCCTGACAAACGGCTCCAGGTA CCCCAACTGTGCATACCGGACCAGCCCGAAGAGAGACACATC ATTGTGGCCTGTGAAGGGAGCCCATATGTGCCAGTCCACTTT GATGCTTCTGTGGAGGACTCTACCTAAGGTCAGAGCAGCGAG ATACCCCACCTCCCTCAACCTCATCCTCTCCACAGCTGCCTC 214 IMAGE:840493 AA487797 5′ TTCCCTCTTCCTTCCCTGCTGTGAAAGAAGTAACTACAGT GGGTTTTACCAGTTTTATTTCTAGACTTTCATGTTTGTCTTT TTGTCTTCTGCTGGAAACATGCCGGTTACATGTTGGTGCTGG GAAGCGCCGCGCTGCAACCAGAAATGCACAGACCCAGCCGCC CGCCGCCCAGACCCTCAGACTTGCGCGTCACAGGACAGACTC CGCTGTGCCCCGTGCACTTGCCACCAGCCTTTGGCGTCTCGA TACACACAACATCCAGGACTTGTGCCCTTGCCCCATCACGAC AGACAAAGCGTCCCTCAAGGCCCCCGCGTGGTTCAGACAGAC 215 IMAGE:841641 AA487486 3′ GCCGCAGCCAGGATGG GCCAGCTCACAGTGCTGTGTGCCCCGGTCACCTAGCAAGCTG CCGAACCAAAAGAATTTGCACCCCGCTGCGGGCCCACGTGGT TGGGGCCCTGCCCTGGCAGGATCATCCTGTGCTCGGAGGCCA TCTCGGGCACAGGCCCACCCCGCCCCACCCCTCCAGAACACG GCTCACGCTTACCTCAACCATCCTGGCTGCGGCGTCTGTCTG AACCACGCGGGGGCCTTGAGGGACGCTTTGTCTGTCGTGATG GGGCAAGGGCACAAGTCCTGGATGTTGTGTGTATCGAGAGGC CAAAGCGTGGTGGCAAGTGCACGGGGCACAGCGGAGTCTGTC CTGTGACGCGCAAGTCTGAGGGTCTGGGCGGCGGGCGGCTGG GTCTGTGCATTTCTGGTTGCACCGCGGCGCTTCCCAGCACCA ACATGTAACCGGCATGTTTCCAGCAGAAGACAAAAAGACAAA 216 IMAGE:841641 AA487700 5′ CATGAAAGTCTAGAAATAAAACTGGTAAAAC TCTTTATTGAATGAGGGTTGTCAGGAGCAAAGGTGGGATCAA GAGCAGCAAAAGCAGAAACAAGTATAAAAGTATCAAAAAATA CAAAGTGCTAGCACTGAGGAGAGTGAGAAGGGTTGGGTTGTG GCCCAGAGGGACCTCTGGGACACAGGATTGAGGACTTGCCAC AGCCTCCAAGGGAACCTAGGCCTGGGGGGCGTGTGCAGGATC CTTGGCTGAGGGTGGAAGTGGCTTGAGCGGGGCCCAACCCTG GGCCGTGAAGTATGAGACCAGTTGTGTGGGCACTTCTGCGAG CACGGTCTGTGCCAATGCCTCCCGAGGGGCATTCTGGAACCG GCGGTAGGGTACAAACTGCACAATGTCGCGGGCAGCACCTGC CCAGAACGTGTATGCAGGGGTCCACCATCAGCGTCCAGCTGC TCCATGGCCTCAAAGTCAGCACCAGCCACACCCACATTGATC ACTGACATGGGCAGGTTCGAGGCACGCACCACAGCCTCACGT 217 IMAGE:843139 AA485922 3′ GTGGG GGTCGGTCTGTTCTTTTGCGGTTCTGCTCTTGCCCTGTGTTC 218 IMAGE:843139 AA486527 5′ TCTTTGTCTC CCAGAGCTAAACAATTTAATATAAAAAATGCCATTTTTTGTC CATACAGTATTTATAAAAAAGTACATAGTGGTTAGTTTTGCA ATAATTTCTTTTTAGCCAGATGTCATATCATCATATAAATCT ATGAATATAACAAATGACATAAGAACAGTATAAATAAGTTTT TGTAGTATTTACACTTACACAGAAACTAGCCCAAATGGTGTC CTAAGAAATTGTTTACAGTTAAAGTGAAACTACTGATTCAAC ATACTGACACTCCAATGCTTTTTAAAGTTTCGTATTATTTTC TATACTAGTTTTGGCTATGATTTTGCATAGAATTACTTATAA AGTATGAGCATTTCACATCACAGTAGGAGCTTTTAGTATAAT AGTACAAAAAAACTAGCTACGAAAAGGTCAAATCCTCCTAAA TCTAGTTTTTCTTAAAATCTGGCTTCTAACTTTGGGAAAAAG AAAACATTGGCATCACTTGTTTGCTGCAGGGAGTATTCACCA 219 IMAGE:884438 AA629687 3′ GGAGAATAAGGTGTTACCTCTTCATCACG TTCATTCAATTTCCTTTAATGAGTACTTGTTACAGTAAAAGA GGTATAAAGTCCTGTTCCCAAGTCCAAACCACTTTTTAACTT AAATCTTGAGTTTTTCTGAATTACTCAATTTGAAGTAATTCT CTTTATATCTGAAAAATGGTTTTATTGAAACGTTTGAGATTA AAAAATATGCATTGCAAGAAGCATATGACAAACATTCTGAGA GTACAAAATTAGTTGTAAAAAATAACATAATTTACCAGTAAA CCCACTCATATAGAAATGTGCAAAGCCTTTTGATATAAAAAG TTTTGTACACCAAGCACCTATTTTTATAACTTAGCTTCCCAT 220 IMAGE:897910 AA598653 3′ GGAGAGA ATTTGTTAAACAGTTTAATTCCCAAAGCTAGTAATTTTAGTT AAATATACATTAGAGCCTTTTTAGATGGCTGCTAATAAACAC TATGTCAAAATGTGTAGTTTTAAACTCAGACTCGAAAGCCAA GATAAGCAACTCCTTCAGTTATTACTCTGACCAAGGCATAAG AATTCACTTAGACAAAAAGCTTTCAAAACCTACCTAAAAATA AGATAGTTCATAAATTTTCAAAACTGTTCTTCCCTGTTGCGG ACAGCCCTTGATCTTTGTAAGACTTAGCAAATTTTGGCATGC TCTCATGTTAGCTTTTTAAGTTACTGAAAACTCCTATAAATT TAGCATCATTTCTCAAATCTGTATAGTTTTCTCATTCCGAAT 221 IMAGE:898286 AA598974 3′ GCTTAAACATTTAGG CCCTACAAAATAATTTATTGGAACACACAGCTACAGCACTCT ATGTACAAGCACATTGACGCTCCTGACTATCCTCAACTAGGG GACCCTTTTCTTCCCCCTTGCCTTGCGGACCTCTTCTATCAA ATCTTTCAGGTACTGGATCTCCTTGGCCAGGGAATCCGCCCT CTCTTTTAGAGCCTCGTTCTTCTTTTCCAGCTCTTTGCACTC ACCAGTAAGAGCCTCCTGCTCCGCCCTCTTCTTCTGGCGGTA CCTAGTGGCTGCTGTCTTGTTTTGCTCCATTTTTTTCAGCTT CTTATCCAGTTTCTCACCCTTTACTTTTGCTGCTACCATCTT CTCTCCAGGAGGATCGTAAGGTTTGGGACGGGCAGACCCACA GAGAACACCTGGAGATGGGAGGCTCCTATTTGGAGAGCCCCT GGTAGAGGGGCTGTGCTGAGGAGACCCCAGATAGGACTCTGG GCTCATACAGATGCCACTATCATTATCTGAAGGGGTGTCTTC CTCCTTTATGCACTGAGGGATCATGGCAACGTAAGCAGTGTA 222 IMAGE:949971 AA600217 3′ GTCTGGCTTCCTATCTCCT TCCAAATCAATTTATTATCCTGACAGCTGGCATCATTAATAC TTTAACAAAACCACTTAAAATTAGCCAAATATCTAAGACAGA TACATATACAAAAGATATACAAATTAAAACCATTTAAAAAGT AATAGATACCATAATTTGTACTTGGCCACAACTTCTGTATTC AGAAATGATTGTAAAATTAAAACCTAAGTTAAAAACTGTACA CCATATACTTTGAGTGATTTACATCTTAGAAAACAAAGGCAG TCTTTCATTGTTACAGATTTAGTGTCTCTGGTGGGTTGAGGA GAGAAACACCATGATACTTTGAATTTTTGTACTTTTCTCTTA TTGACTGTTGTGCATGCTGTGGTGCTTTGAGGTAGGTCTGGT GAAGGTCCATGAGACAAGGCTTAAGACTTTCCAGGGTATATC CAGTCTTTCGTATTAATGATTCAGGCCAGCTTTGTCCCGTGA CTGTGTAGAGTGCTAAATGAAAGGCAGCTCCAGCAATAACTG ATGGCAAATACTTGAGGTATGGGTCAGCATCTATCAGACTTA ATTCTCCCAAAAACATTGCTAAACTTTCAACTTTGCAGTTTG CAGGCTACTGATGCAGAAAGTATTGGGGAAGAAACTGATTTA CTGGTGGGAGCAGCTAAGTCAAAAGTAAGGGACTTTCAAAAA CTAGATGGCTCCATTGCTCAGGAACTTGTTTACCTGGGTGGA 223 IMAGE:950690 AA608568 3′ GG

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1 302 1 380 DNA Homo sapiens misc_feature (1)..(380) n is a, c, g, or t 1 gctataacat ggcagcctcg catcccttcc tgcttaccac ctttctagat attaaggctt 60 acttagttct tactgaatta aatggagagt gacttgacaa ctcttggcca gccattctta 120 atgatatttg tgttcctaag atatagcagt atctgcaaat cctaaatctg tctcatgaag 180 attttatgat cttttagatc agtgattaat gggaaggaca atgtccttta tttttttaaa 240 taaaaaataa tgacctggaa ctttctctgt aggccaataa agggtgagtg tggatggggc 300 tatcaccctt gggtngtgtt ngggagttta acatttctct aggtttaaaa ccatncctat 360 naccttncca caanaccggc 380 2 281 DNA Homo sapiens misc_feature (1)..(281) n is a, c, g, or t 2 ataagcccta gatatgattt aatttgaaga ctagttcata tttttacttt tganccaatt 60 ctagtctcat aaaataaaaa ttcaggtctc tctgggtcac accacacatc taaaagttga 120 cagtatggtc tggcactaca gtctccttct aggagaagtt tgggaaatca ttctaacccc 180 tagttagctc catgtatctt aagaatcacc aattatttga aagcttggag gttctaggag 240 gggagtgcag ctactcatat acccttgacc gagactgggc c 281 3 435 DNA Homo sapiens 3 ttcacaatcc aaatctcaaa ttacagaaaa atgatatacc tttcagctat gtttttttgt 60 gtgtgtgttg gctgggaatg ccaaaaaggt tggcaaaagg ggcaggaaaa aagtagtggg 120 gctctctggt gtactccact cctcacatgt ctaccattct gagatttttg atgtcaggtt 180 ctgccaagtc tcaaaacctc aagagttgcc agaattcagt cccagtgtac acattctact 240 ctagggagag gaaggataac aaccacccaa gggccaccca cccgaggaca gccctgcctt 300 ttaggtatgg gggatgcggg tgttcattca atttgctttg gggtttccct tcttgaggtc 360 ccaggaaagg aggattttcg ggggagttca ctttcttgcc cttcaggtcc cgggggggaa 420 ggcaacaggg ttgat 435 4 406 DNA Homo sapiens misc_feature (1)..(406) n is a, c, g, or t 4 angtcanant ngggttatca ggcatcagtc tacctgagga ggcaacagca ttggtgggtc 60 caccagtaaa aaatggacag gagactgctg tgcccccttt gtgggaaaag cctcccttgg 120 gaagcagtgg ttgtatgctc agtcctcccc tgggaagaac aacaacaggc aacttgcagg 180 gttcccttca gaatgtctct ctgagtgcac ctgggcaata agcaggcaca agaccctggg 240 gtgctgaacc ctnttcaaca gcctgggcag gcaacgagga cattcaggaa ntaccagcca 300 ggaaaggcag gaaccgtttt gtttggggtt cntttcccac aaccgccntg ttttttcccg 360 gcaacagttg attttnagga aggcaaaaga aggaaanttt tcaggg 406 5 301 DNA Homo sapiens misc_feature (1)..(301) n is a, c, g, or t 5 taactgggaa ttgagaacnt gcagttcaca ctcaacagta ccagggcaga aatgaactaa 60 tgcatgcaat ttatttagcc tatcatgtgg gctgtgagtt tttcctggaa catccgggct 120 ggttttcttc tcttggnata atggtttatt acatgtgaat catatcataa cataaacttg 180 ttagttcctg attcccgata aaaaagacat tttattgaac aaatgaacag ttcaaggtct 240 aaggcaatga ttaaccgagc cagtattaaa tgctctagnc ctataagggg aatatcccat 300 a 301 6 284 DNA Homo sapiens misc_feature (1)..(284) n is a, c, g, or t 6 aggcaggaac atgggttatt tatgaaggat gcctgtagag ttcaacaagc ctgcttactg 60 cgggttagtt gtgaccattg tctaaggtaa tttaatggtt ttcctatgga ggagctgaag 120 ggagccntga aaggggaaaa gggtggctcc caatgagttg gcagccaatg gggaacaatt 180 tggatataat aaataggtct catgttgact cctttccaaa acggcctttc aaaggggnag 240 tgtnggcttg gcctggcaaa cttctcccca cccactncac caca 284 7 288 DNA Homo sapiens misc_feature (1)..(288) n is a, c, g, or t 7 gaatttttat tttaaaacaa agaatcaaac aaacaataat ggaaaatcca tatggaaata 60 ttcacaatct tctcagtgag aaataggaaa acaacttccc tgccttactg ccaaactgag 120 gagccagaag ttgacgtgaa gttggaaggc cacctttcca gctaaacccc actccatagc 180 tacgtgcatt tttattcaaa ggctccaggg ggcagaggga acagtgagga ctnaggaccc 240 aaaatacttg tcactgggca agggttttgg cttaaagggg tcttgagg 288 8 315 DNA Homo sapiens misc_feature (1)..(315) n is a, c, g, or t 8 gaatgtttat agcccaaact tggaatttgt aacctcagct ctgggagagg attttttttt 60 gagcgattat tatctaaagt gtgttgttgc tttaggctca cggcangctt gntaatgtct 120 gttaccatgt cactgtggtc ctatgccgaa tgccctcagg ggacttgaat ctttccaata 180 aaccnggttt ngacagtatg ngtcaatgtg cngtgcagcc cacacttnta ganggatgaa 240 tgtatgtgca ctgtcacttt ggctctgggg tgggagtatg tttattgttt gacttatttt 300 ctctgtgttt gttcc 315 9 422 DNA Homo sapiens misc_feature (1)..(422) n is a, c, g, or t 9 ttcttgatag catcacattt tattactaat tgcagttttt gattccacaa ccctgtataa 60 cttggcattc tggtgaattg gacccgaaca tctgtgaatc ttaaaaatag tggttgactc 120 attatggctt ccttatgtat aggattaaga acacagatcc tgggaatcag acagcctggc 180 ttccacactc tagctgggtg accatgacca tgaagaagtt cctgaatgtt ccagtgtcag 240 tttattcacc tttacagaga aatctggcca aacactaccc tcagccaggg tgatccaagt 300 tcaatattca gcaattaagg tcatgttgtt tgttaggtgt gtgctcttga tatggcatga 360 tgaggaattg cacttcactt ctgtgatatt cccccngggc ttttaacttc aggtccctgn 420 aa 422 10 377 DNA Homo sapiens misc_feature (1)..(377) n is a, c, g, or t 10 natttcggca cagagcgctt ccattgctga cctctaccga cctctacctg tggtccttcc 60 tctactgcag cagagacact gttttcttcc tttgttcttc caaccccatg gcacaganac 120 actctccact gcggccaagg attgcaggag aggtggcatc agtgattcaa gactgctttt 180 cctacctctt cagtgtttct ttcagtgatc tgaagttaaa gccaggggga atatcacaga 240 agtgaagtgc aattctcatc atgtcatatc aagagcacac actaacaaac aacatgactt 300 attgctggaa tattggaact tggatcactg gggtttgggt agtnttttgc cagntttctc 360 ttgtnaaggg tggatta 377 11 344 DNA Homo sapiens 11 gcttcttctg ggcacattgt tctgacataa aggttgcctc cttgtggggg agaaggggag 60 gattagtttg ttggcttggg catttgatca taaattatgg aggtgctgga ccggagaacc 120 acccaccagc ccacggaggc taccgggcat tcaggataag ggccgccttc ttcttcagaa 180 taaccatacc cactccctct gaaacaaagt ggagagtctt aggtctgagt ggaaactcta 240 aatcttttaa ttcttgggtt caactttctt catctgtttt cctgggttca gactaaaacc 300 atctaactca gctgggagaa gttataaccg ctttgttgtt gggc 344 12 285 DNA Homo sapiens misc_feature (1)..(285) n is a, c, g, or t 12 taccccgaca gtcttcacac acacaaaaaa aaaaaaaaaa agaaagacag accaagcaga 60 atnaaataaa aggtctgaag aacaagtttt gttaatttgc cacaacagac tgtactccag 120 gggaagcttt gttgtccatt aaagtgagtt ctctgggaag acgagtagta accgacttgc 180 acgattttcc tgccttttct atattctcta cttactatga caatacagca ctaggnattt 240 ccaagtgctt attacccggc ataggtgcat gtattttaat gaggg 285 13 380 DNA Homo sapiens misc_feature (1)..(380) n is a, c, g, or t 13 ttggntnnga agaaataaaa ctgcctttat ttgcagataa caatcacata catagaaaat 60 cctaagggat ttacaaaaaa agctgctaaa actaataagg agatttaaca gtattgcagg 120 acacaaagca tttctgtatc ctaacaaaga ntaattaaaa actgganttt aaaaaattat 180 ttaggctggg catggtggct cacacctata atcccagcac tttgggaggg tagctggatt 240 aaaggccaca ctgccacacc catctaattt ttgtattttt agtagagacg gggtttcacc 300 atgttgggct aggctggtct caaactcctg ggcctccgac ctcagcctcc caaagtgctg 360 gggattacag gtttgaggcc 380 14 453 DNA Homo sapiens misc_feature (1)..(453) n is a, c, g, or t 14 gcttttgcac atcaataggt atccctagga gggcctgatt cagaagccct catttttaaa 60 ctcaattctt agatgaacag tcttattcat ctggaatgtt ccacataatg gtcatcataa 120 ttctaattta tctttagtaa gatttcacca tttttgtaag tatttgcagc ttctaggccc 180 taacacatgt aaaaggtaaa catagccagg aaggtgaaat acacagttct ttaaaaattt 240 aagggatgct ggccagggcg aggtggcttc acacctgtta atcccaggca ctttggggag 300 ggctgagggt cgggagggcc aggggagttt tgaggaccca ggccttaggc ccaacatggg 360 gtggaaaccc ccgttcttct acnttaaaat ttaccaaaat ttaggttggg gttttgggcc 420 gttttgggcc cttttattcc cngttaccct tnt 453 15 221 DNA Homo sapiens misc_feature (1)..(221) n is a, c, g, or t 15 acggtagtgg gtagcgggtc tcgggttgcg ggttgcaggt tgcaagccna gcccgcaggc 60 aactnccttc ccggcgccat gttcggctcc agtcgtggag gcgtgcgcgg cgggcaggac 120 cagttcaact nggaggacgt gaagactgac aagcagcggg agaactacct gggcaactcg 180 ctgatggtgc cagtagcnct tggcagaagg gccgcganct c 221 16 342 DNA Homo sapiens misc_feature (1)..(342) n is a, c, g, or t 16 ttttaacccg gtcaagtcca aaggtttatt ttaaggcaca aggtgggngg ncaaggggga 60 tggtaaaagc gcaaggggtc gtggcctcat caaggtccga aggtccaagg gaaggcgggt 120 ccggtcctgt tggtcctggt cccgaattgg tagctgggtg tatctccgga ccatgttggg 180 ggcgcaccat cccttcctca ctgggacctc ctgggctggt ccangccctt ctcctcgggg 240 tcgcctcctt cccgcttgca agacctcccg cgaagtcctc cttgctcaan gcccgtgggt 300 tgcttcttca ngttcttgta gccaaggggg ccaanaagcg ct 342 17 226 DNA Homo sapiens misc_feature (1)..(226) n is a, c, g, or t 17 ctttcttatc tttcagtccc ccatatgccc tcctccaata gaatgtttga aattacaaaa 60 ggttcagaca acaccataga aggaaagaaa ttacaaatgg nacactattt tgtgtatatt 120 tgtttttaaa aatttctgaa tctgcattta atgaattttt attgaatgat gtgttgaata 180 tttgttaccn ataattattg aaattattga taattaatga taatta 226 18 356 DNA Homo sapiens 18 tgtcatagac caatgcgaag tttttggcca ttaaatattt ttctctgttc taaatgcaga 60 gtcttagaag caagacgtac ttttcaattc atatctttct acattatatg aattatattt 120 cacaataaac atatttattt ctttagagat ggagttccgc tcttgttgcc cagggctgaa 180 gtgcaatggt acaatctcag ctcacctcaa cccccacctc ccagggttca aggcgattct 240 tctgcctcag cttacccagg cagctgggga ttacacccgt gcgttcacca tgcccgggct 300 taattttgta tttttagtag aggacggggg tttctccctg ttgggtcagg gctggg 356 19 408 DNA Homo sapiens misc_feature (1)..(408) n is a, c, g, or t 19 aaaggancct ttattgacca gagcaggacc gtggcatttt tatatatata tatatatata 60 taaaagtntg aagacctggc aggcagtgat ccnattgtcc gcccaccacc cccagcactg 120 atttcctgct ccctgcacgg ggaaggggga ggatgactnc tccacccagg ccacagggca 180 cactcccctg caaacagagg aagaaagggg cttttctgta gccaccccct gcacatcaga 240 natcaacaag tattctctca aannaannnn nntacagnnt ttganncatt tnnntntgnn 300 annccnnngg gnngtgagtg gggnngnggc nngngnggnn nggnctgggn gtttcttggg 360 gnngggnctc ccntgtctcc cttcccnttt atggggnttg ggggtctg 408 20 402 DNA Homo sapiens misc_feature (1)..(402) n is a, c, g, or t 20 ggttatgatg gggtgaaaag gtggaccaaa aacgtggaca tcttcaataa ggagctactg 60 ctaatcccca tccacctgga ggtgcattgg tccctcatct ctgttgatgt gaggcgacgc 120 accatcacct attttgactc gcagcgtacc ctaaaccgcc gctgccctaa gcatattgcc 180 aagtatctac aggcagaggc ggtaaagaaa gaccgactgg atttccacca ggggctggga 240 aaggttactt caaaatgtac tgcaagcatc tggccctgtc ttcagccatt tcagctttca 300 cccagcaggg acattgccca aatttcgttc gggcagatct tacaagggag ntgttttcac 360 ttgcaaattc attgttgttn ggcctngtta ccccaggacc cc 402 21 382 DNA Homo sapiens misc_feature (1)..(382) n is a, c, g, or t 21 taaacataan nnntacaaag tatagtcttc gtattcacta cacaccgcaa agttctgcta 60 cttgaaataa agcaaatgaa gaaaattacg ttttctgaca taaaaataat tattatatcc 120 actggcaaca ataaggaaaa cttagcactt atatatttta tgatcaaatt gattcaaaaa 180 ttaaattggt tagcttcagc atctattctg tctatatctc cctgtgggat gacaatttag 240 acaatatgaa cattctcagg ataaggaaat cttgttttaa aatgtcccag gcatcccttc 300 cnctggttaa aactccctat atttgcctta ttataaaatt cagggctttc ttccnccagg 360 tgggcccaat ggcccaaggg ac 382 22 287 DNA Homo sapiens misc_feature (1)..(287) n is a, c, g, or t 22 caaacatcca aaccatttca gaactcattc tataaaatat ataaacagct ttctattttt 60 tttctagctg cataatattc cattgtgtgg atgagccata atttatcaat ttcctattat 120 ttctaatctt ttacaataga tagtgtttca gtccttaatc ttatacatat aggtggccat 180 aaatttttaa ggttctttgg gctatttggc caacatgtgg gaaggaaagc cttggaattt 240 tataataagg caaatatagg gngttttaac agtggggagg gatgctg 287 23 363 DNA Homo sapiens misc_feature (1)..(363) n is a, c, g, or t 23 gaacagttca atcctgggct gcgaaattta ataaacctgg ggaaaaatta tgagaaagct 60 gtaaacgcta tgatcctggc aggaaaagcc tactacgatg gagtggccaa gatcggtgag 120 attgccactg ggtcccccgt gtcaacttga actgggacat gtcctcatag agatttcaag 180 tacccacaag aaacttcaac gagagtcttt gatggaaaat ttttaaaaaa ttccacaaag 240 agattatcca ttgagcttgg aggaggaagg ataggacttt gacgttgaaa ttttattgaa 300 cggcacttct ttaaaaaggt tacccaaacc aggnccacag gattnatttg gntttttttg 360 ggg 363 24 490 DNA Homo sapiens misc_feature (1)..(490) n is a, c, g, or t 24 gatcaagtta ggaaacacac gattgaaatc tggaagagaa aactggctcc taccacattg 60 cttctctcga tcatgggtga agcctgagga gttccagaca cgggggtaga ggctggggtc 120 tttatttctt cgatcatatt catgattttc tctgggcact ttgatggcat caacacaggt 180 ctcctgccac cgaggcagct tgggaattca gtagttctgc agactgtaag tgataataat 240 gtatgtgggt tttgcaaagc cacagtgctt attcaaccca ggaaagcagg aagcgcctct 300 ttctctttca agcaggagcc tcntttggca acccntcttg gcaatggant ttctggggat 360 tttcacttct ggacggagga agttaaccgg gttnttccca ccatacttcc aatttccttt 420 tggtggtttc caaattttgg agtggcgttt tcgggccttc ccttggggnt tttcccntcc 480 tgaacctttt 490 25 359 DNA Homo sapiens 25 tacacatgtg tatgcatgaa aaatttctag agggtcatat taatgtaaga aattgtgaag 60 ggtggtctct agggcatgga gcttagcagc tagtgataaa gaaactcact tgtcattaca 120 cttactgttt gaatttacaa tgtcatgttt cattttcata atttaaaaaa gtcagtgcca 180 aaacacttac ataactactt acatttctta tgtatgattt gactgcttat tttaaagttt 240 actgtattta aagttcaaca tcaaaagaaa gggctaggaa aagtgggtgg gctaggacct 300 aggttctttc acactacttc atttctaggc ttccacatgg ctctggtaat agccaaggc 359 26 328 DNA Homo sapiens misc_feature (1)..(328) n is a, c, g, or t 26 agtttctgtg ttcaagtttg aatactcttg aagtcttatt tttttcattt tcagatttta 60 aaattttcaa agaaaaggcg ttgctgatgt ctgaaatctc agatgcctga aattcaattg 120 acaattactg aacaacagtc tcttatttac ataaaggtgg ggttgtcaat cttgggctct 180 caggaatttt ctcttgtagg gcactgtgta ggctaaaggt tatttaaggt gatttcagag 240 gtaggatagg attactcagt ggattactac cctgttgcca aggttaattc cggnaggggt 300 aacccccgtt nccagttcac gttagngt 328 27 369 DNA Homo sapiens misc_feature (1)..(369) n is a, c, g, or t 27 agaacaggta cttcgtactg ggatttcgag gctggcatcc tgcagtattt tgtgaatgag 60 caaagcaaac accagaagcc tcgaggagtc ctgtctttat ctggagccat agtgtccctg 120 agcgatgaag ctccccacat gctggtgggt gtactctgct aatgggagag atgtttaaac 180 tgagagctgc tgatgcaaaa gagaaacaat tctggggtga ctcagcttcg agcttgtgcc 240 aaataccaca tgggaaatgg aattcttaag gagtgctccc aagctccccg aagccgaagt 300 cttcactttt gcttcccaca tgggaacacc cattcttgcg tcttccctgt taggccagag 360 acacctnaa 369 28 410 DNA Homo sapiens misc_feature (1)..(410) n is a, c, g, or t 28 gcctccatag aaaggcttcg tgtggaatat cactgtcgct gagtacccag tcttggcaca 60 gttgatgctg acttttcctc cgagctccac ccacgggatg gtgagaatgg accgggcgta 120 ggcactaggc agggtgaata cgtactcctc cccgtgttcc aggagcctca acacaccttc 180 ccctatcata gagaccccca cggacatgcc catgaacttg cttttggtcc atacatgagt 240 gttgacgcac agtctcttct cctcgcactc acagtagaag caggagatgg gtgggtgatg 300 ggacacttgc tcagccacaa accttagttt gtagcttttg ggaagggtca tcggccattt 360 gggtnttcat gacagctggc aggagagccg ggaagcagtt ctctttaggt 410 29 301 DNA Homo sapiens misc_feature (1)..(301) n is a, c, g, or t 29 gccgcatggg aggcatggcc ccggggtcct ggtggccact cgtgcctggt ggagagcgag 60 ggcagcctga cggagaacat ctgggccttc gctggcatct ccaggccctg tgccctggcc 120 ctgttgcgga gagacgtgct gggggccttc ctgctgtggc ctgagctggg tgctagcggc 180 cagtggtgtc tgtccgtgcg cacgagngcg ntnngttgcc ccaccaggtc ttccggaacc 240 acctggggcc gctactgctt ggagcacctg ccggcagagt tccccagcct gggangcttc 300 t 301 30 389 DNA Homo sapiens misc_feature (1)..(389) n is a, c, g, or t 30 gtcgagttag gaagggccct ggtcacccct ctaagcctgc agctcactgc tggcccctcc 60 ctgtcaaatg gctaaaggag atgagctggg ggtgggggtg ccctggtgat tcctaggggg 120 aaggggtgag cctgcgcatc ccttctgaga aagcgggagt cacagccctg aggttttgag 180 tggagacagc atggagattc ttggccctgt ctgctggtgc gcatcccttt ctgcacacag 240 gagtccaccg tgcgtgangt ttaggtacag ccctctgtcc ctccttgccc tctcttgcac 300 cttcccaccc ctcctttcac ttttcagatn acatattgag gaaacagccc tngttctgtt 360 cagcntagat gggggttcat ccccagcct 389 31 290 DNA Homo sapiens misc_feature (1)..(290) n is a, c, g, or t 31 gagtttaatg attacatggn gctgagtcag gaggtaggag gagattctta aatctctgaa 60 gagttctggg ctggggttct gggaggcaag gggctggaaa atttgggcca ctgattggtc 120 agggtaaggg agattgaatc attaggatat ggaaattgca ttctttgatg atttagcttc 180 tggtagggnc cttcagacca ggctgacatc agtagtttca tcagtatgca gggncaacca 240 atcatggcca agtccncttt naggganttt gtncccgtag gatttatccg 290 32 417 DNA Homo sapiens misc_feature (1)..(417) n is a, c, g, or t 32 gctgatcgaa cagcctcact tgtgttgctg tcagtgccag tagggaggca ggaatgcagc 60 agagaggact cgccatcgtg gccttggctg tctgtgcggc cctacatgcc tcagaagcca 120 tacttcccat tgcctccagc tgttgcacgg aggtttcaca tcatatttcc agaaggctcc 180 tgggaaagag tgaatatgtg tcgcatccag agagctgatg gggattgtga cttgggctgc 240 tgtcatcctt catgttcaag cgcaggaagg aatctgtgtt cagcccgcac aaccatantg 300 tttaaggcag tgggatggaa agtggcaagc ttgcccaagg aaaangggtt aaagggaant 360 tttttgccac agggaaggaa acaccntggg caagagggna ccatttacca gggggca 417 33 318 DNA Homo sapiens misc_feature (1)..(318) n is a, c, g, or t 33 accagaaaat aagacatttt attttgagaa ataaattgga aaaaaatatt ttaaaatgtt 60 taatttgcaa tatacataat actggaattg aaatgctgtc tgatggaaat gttgcaatgt 120 ggagtaggag ggtcaagttc gtgaagatat tcttaaaatt aatcttggaa actctgtgcc 180 tatgaggttt ctctaaagtg gctaaaatat gcatttaata tgttgtctaa atgagtacat 240 ttaattctag agactgtaag gagtaggaga ttatatgctt tgggggcttt tgtaggcntt 300 ttttttaaaa tcagttgt 318 34 368 DNA Homo sapiens 34 taaatgcatt attcatattt cttgaagctt agatacagtc taattcatag caaccatatc 60 tgctttatcc taggtgaggg tagcagtcca caatggaata gaagaaaatc ccattataac 120 aaatgacaaa ttatatatca tgaatccttc tgtctgacta actcaataac tttctataaa 180 agccaatgga attcaaatag gagctaggag acaacaagtt atatatgaca gtggaggttg 240 tattcctttt atattgctga gaaaactagt taaatgatca gattcttggc tgttaaggaa 300 acaattttcg tttaatgggg atctgtacaa ctgattttaa aaaaatggct acaaaaaggc 360 cccaaagg 368 35 441 DNA Homo sapiens misc_feature (1)..(441) n is a, c, g, or t 35 ttttttatcc ttcttaannn ttattacatg ttttattatc ctgtccccag aggtgggttt 60 atccagaaac caagaaaaaa aatcaatcag aataaactca aaaaaaaaag gtagggggag 120 caaaaccatc aaccaccagg gcagccaggc catcagccca cctccacctc tggagggtcc 180 ccagagaccc acgcccgacg cagacccgga ggaggcatca gcaagggggc ccgggcagag 240 aatcggctat gtctttcatt atgaggaggc agggagagac gggcagagat atgtttgcta 300 gggtgantat atattttata ttaattaaat ccgtaagttt aattaaagta aataggtatt 360 tctctggaag tttttttaat ttctttcntt ttttatagtt tttttggttt tttgtggntt 420 tttttttttt ttttggggtt t 441 36 126 DNA Homo sapiens 36 caagcacccc gcttttgcag cagaggagct gagttggcag accgggcccc cctgaaccgc 60 accccatccc accagccccg gccttgcttt gtctggcctc acgtgtctca gattttctaa 120 gaacca 126 37 409 DNA Homo sapiens misc_feature (1)..(409) n is a, c, g, or t 37 ggaatctact ncgagcacag caggtcagca acaagtttat tttgcagcta gcaaggtaac 60 agggtagggc atggttacat ntttaggtca acttcctttg tcgtggttga ttggtttgtc 120 tttatggggg ggggtggggt aggggaaagc gacaggaagt aacatggagt gggtncagcc 180 tccctntaga acctggttac gagagcttgg ggcanttcac ctggtctttg accntcattt 240 tcttnacatc aatnttatta gaagtcagga tattttttag agagtccact ntttctggag 300 ggagattagg gtttcttgcc aagntccaag caaaatccac gtgaaaaagt tggntgatgc 360 aggtacaggn ttacacgngg gcatagtttn ccatagtcng ttgccaggg 409 38 412 DNA Homo sapiens misc_feature (1)..(412) n is a, c, g, or t 38 ccagtcacca agacaggcat ctcaaatcgg ctgattctgc atctggaaac tgccttcatc 60 ttgaaagaaa agctccaggt cccttctcca gccacccagc cccaagatgg tgatgctgct 120 gctgctgctt tccgcactgg ctggcctctt cggtgcggca gagggacaag catttcatct 180 tgggaagtgc cccaatcctc cggtgcagga gaattttgac gtgaataagt atctcggaag 240 atggtacgaa attgagaaga tcccaacaac ctttgagaat ggacgctgca tccagggcca 300 acttacttca cttaatggga aaacggaaag attcaaagtg ttaaaaccag ggagtttgag 360 gagcttgatg ggaactgttg aattcaaatc gaagggttga agccaccccc an 412 39 394 DNA Homo sapiens misc_feature (1)..(394) n is a, c, g, or t 39 ntccacgatc tgctcanncn gngaccacgc ccttggcagt tcgccctcgt agtagatgtc 60 taccacctcg gccgtgaacg tcctgatggc ttcccacacc aggagcccgt cgtcccggta 120 gaagtagtag gggatgtctt ctttgctctc catgccccgg gccttgatgg cctcgggaaa 180 gcacagggag gcataggtca ggtccttcat ggccctctgc accatctgca cgtgcccacc 240 gccccctgtg gcgttggcct tgtcaaagag gccacactcg cagatgagct gctcacgggc 300 cttgggtgtt gattgcaatg gtaaatctca cgtgtgccac cagcagcttt gaaaatgggg 360 gtgcacagca gggcagctng gcggtaacat ttgc 394 40 371 DNA Homo sapiens misc_feature (1)..(371) n is a, c, g, or t 40 ctgggcgaga tccagctggt cagaatcgag aagcgcaagt actggctgaa tgacgactgg 60 tacctgaagt acatcacgct gaagacgccc cacgggacta catcgagttc ccctgctacc 120 gctggatcac cggcgatgtc gaggttgtcc tgagggatgg acgcgcaaag ttngcccgag 180 atgaccaaat tcacattctc aagcaacacc gacgtaaaga actggaaaca cggcaaaaac 240 aatatcgatg gatggagtgg aaccctggct tccccttgag catcgatgcc aaatgccaca 300 aggatttacc ccgtgatatc cagtttgata gttgaaaaag gagttggact ttgttctnaa 360 ttactccaaa g 371 41 400 DNA Homo sapiens misc_feature (1)..(400) n is a, c, g, or t 41 ttatttaaaa cttaattctc accttgagta tgcaaaatac aaactccaca aaatgttcat 60 tttactttgt agtttacaaa tatacaaaat agacgtttgc ttaaatttat attacatatt 120 tattaaggca aggaactata tagaaaaaca catttgttct gcttaaggca tacttgggaa 180 taaaccattg tacaaattat tgcacatctg aaaccacagt gcataacaga ctgtctgcat 240 aaaaatgcta aagangtaaa ccagggtata ttacctgact tagggtcata aatgttgatc 300 ggaggacaaa tataggattt tccttgtcaa agtatgcagg cagtttgaaa actttgggct 360 tccntgtttg ggnaccttta gganccaagg tctcaccaag 400 42 471 DNA Homo sapiens misc_feature (1)..(471) n is a, c, g, or t 42 ctggacttac aaaatgccaa gggggtgact ggaagttgtg gatatcaggg tataaattat 60 atccgtgagt tgggggaggg aagaccagaa ttcccttgaa ttgtgtattg atgcaatata 120 agcataaaag atcaccttgt attctcttta ccttctaaaa gccattatta tgatgttaga 180 agaagaggaa gaaattcagg tacagaaaac atgtttaaat agcctaaatg atggtgcttg 240 gtgagtcttg gttctaaagg taccaaacaa ggaagccaaa gttttcaaac tgctgcatac 300 tttgacaagg aaaatctata tttgtcttcc gatccaacat ttatgaccta agtcaggtaa 360 tataccgggg tttanttctt taggcntttt tatggcagac agtctgttat ggcacgtggg 420 tttcagatgt ggcattattt gtacatgggg tttnttccca gnatggccta t 471 43 409 DNA Homo sapiens 43 tgcacattct gtttttacct ctgtcactga ctctgtgggt ctagccatgt catttaacca 60 cacttgaatt tcaggtattt tgtctgtaaa atgaggataa taacgcctgt ctactacatt 120 aaaccacaag atggtttaaa ggttagcata ataaattatt agagtatgac ctaggagtta 180 cctaatctga cctctttatt ttacagatag aagtacagaa aggtaaattg aattgctcaa 240 ggtcacccag tgtgtggcaa aatcagaact ggaaacttag gtcttctgcc agtcccattc 300 aagggctttt tccattgtac agttaaatta tatgttgtgt gtaaggcata gtataaactg 360 taaaccattc atgccaaatg ttcaggtgga ttgtttttcc ctcagtttt 409 44 389 DNA Homo sapiens misc_feature (1)..(389) n is a, c, g, or t 44 ctccttctct tcttgttatt attatcatta ttattatttt gagattgatt actttcccat 60 aaaagtggaa tatactttgc tttggttgag taatgctcta attatctgag gtcttacagt 120 aattgattca gactgatgac cacctgctgc ccattccaca tgggcaggga cacagcaata 180 atgagaatta gggttaggct cataggggat ggaagccagc agggaaggga ctaaagcttt 240 gggagaaagc tgaagggtga ctactgcccg ggggcttgaa ctttctaatg ggccatggcc 300 ttnctctgaa aatgtaatta ctatgaccac tgggttaggt gatgtatttt tcatttctta 360 cccactctcc atccctttta aacactgca 389 45 448 DNA Homo sapiens misc_feature (1)..(448) n is a, c, g, or t 45 ggcccagatc ctctggactc ctcagatgag cggattcaga gagaagcttt tcagagcgtg 60 ctggcggaga catttttcac aaaagagccc ttgcgntgct ggtgtccgtg gcgtgcctgg 120 gaagnccacc aacgctggcc ggcctccaag cacccgggcc tctgctcatg tacagctcct 180 gaactgccct gcctctgagt tactgtggaa aatgagctta tatatgaaga agtcagcgag 240 tggacaaagc caggcgcaat ggatagcaaa gatgtgggaa gtctcctcga ttcaagttac 300 aagaaaaccg cagcatggag tctnctctca gctgtttggg ggnattaccg atgnctttga 360 ctaagtcaag actgactttt tccagtaatt atcacccaag nggttaggag gncgttccct 420 gttccaagtt ttttgncgtt agcntttt 448 46 401 DNA Homo sapiens misc_feature (1)..(401) n is a, c, g, or t 46 gaagggcatt ctcaaaacgt nnccgcacaa gcagaccatc ccttttattt tccccgtctg 60 tctcctttcc ttctgctttc aaaatgtctc aagagtattt acaagagttg agcaacacag 120 gcatctttat ctggggtctt tatccacaga gcagaggaca ggaagtcatc actacagaga 180 cgaagcgatg tatggtttga cccagtggag gactttgtta aggtggaggt ntgagtntgg 240 agtgtaaacg tgggacatcc aggggcagtg gagggtaacc actgggagag gaagtctggg 300 ggacagtttg gggagccagc caaatntaaa aataaagcat ttctgttcta aatccaaatg 360 aacctttnta cgctgctgtc atcttccagt ataccccagg g 401 47 488 DNA Homo sapiens misc_feature (1)..(488) n is a, c, g, or t 47 ctaaggaagg gcccatcctc actgcagaat cagaaactgt cctccccagt gattcctgga 60 gtagtgctga gtctacttct gctgacactg tcctgctgac atccaaagag tccaaagttt 120 gggatctccc atcaacatcc cacgtgtcaa tgtggaaaac gagtgattct gtgtcttctc 180 ctcagcctgg gagcatctga tacagcagtt cctgatcaga acaaaacaac aaaaacagga 240 cagatggatg gaatacccat gtcaatgaag aatgaaatgc ccatctccca acttactgat 300 gatcatcgcc ccctccttgg gatttgtgct ctttcgcatt gtttgtgggc gtttctcctg 360 aggaggggaa antcatggga aacctatttg tttcgcagaa acacacaagg gttaggatta 420 cntgggagat agttaaaatt gttcctcaat gacgtggcag gcttggaggg ggagacgaag 480 acggcctt 488 48 374 DNA Homo sapiens misc_feature (1)..(374) n is a, c, g, or t 48 tgaaacaagg aaatctacta agacttattt tgacactgga gtgtcatgcc cccatcctca 60 atctaacatg ctactgcgtt gttagagggt aaaaaggccg tcttcgtctt cccttccatg 120 ctgcacgtca ttgaggacat ttttactatc tccaatgtag tctagccttg tgtgtttctg 180 cgaacaatag gtttccatga gtttccctct caggagaaac gccacaaaca atgcgaagag 240 cacaaatccc aaggaggggg cgatgatcat cagtagttgg ggagatgggg catttcattc 300 ttcattgaca tggggnattc catccatctg gtccngtttt ttgtnggttt tggttcngga 360 tccaggggac cgcc 374 49 385 DNA Homo sapiens misc_feature (1)..(385) n is a, c, g, or t 49 tacgttttgt atgttttttt atttgctcca ggtggggttt tgactgtcac tttcccacac 60 tctggattag ttctgatccc accacaagga gccctcgaat tggctaaagt gagaaactgg 120 gcctgaagac tccgtaccct ctgccatctt gccgagggag tctcctttta gaaaacaatc 180 aaagggttat tgcatgagtc tggatgaatc ccactctcag ctgtccacgg gcccgaccac 240 ctcatctagc cccctttttg gcagggagaa cctgggctcc caagttctcc tccttcactt 300 cgttacaaac caaggggaag agcccaccgt gagaacgcgn catctgcaag ctgtctccct 360 ttttncatcc ttggtngaaa ccctt 385 50 437 DNA Homo sapiens misc_feature (1)..(437) n is a, c, g, or t 50 tnttttgttg nctctagcct gancagatag gagcacaagc aggggacgga aagagagaga 60 cactcaggcg gcacanttcc ctcccagcca ctgagctgtc gtgccagcac cattcctggt 120 cacgcaaaac agaacccagt tagcagcagg gagacgagaa caccacacaa gacatttttc 180 tacagtattt caggtgccta ccacacagga aaccttgaag aaantcagtt tctaggaagc 240 cgctgttacc tcttgtttac agtttatata tatatgatag atatgagatn tatatataaa 300 aggtactgtt aactactgta caacccgact tcataatggg tgctttcaaa caggcgaggt 360 gngtaaaaac atcagnttcc acgttngcct tttgcgcaaa gggtttcacc aggttgggga 420 aagggngaca gcttttt 437 51 273 DNA Homo sapiens misc_feature (1)..(273) n is a, c, g, or t 51 cattaaatca gagtacttaa tgatacggaa aaaattccta ttaagtgaaa aaagcattac 60 aaaacagcat atattatgag ctctattttt atttttgaaa tatatttatg cagagaaata 120 caaaatgtta acaatattat cttaaaanaa aaaaatangg ctgggcacag tggctcacac 180 ctgtaatccc atacttttgg aggcaaggtg ggtggatcgc tttgagccca gggngttcaa 240 gaccagcctg gggcaacatg ggcgnaaccc cga 273 52 251 DNA Homo sapiens misc_feature (1)..(251) n is a, c, g, or t 52 tgttcctccc cnntccccca gggataagaa cctgttatcc accatcagta acattttatg 60 aaagatctac ttatttgtct gttttgcaga cattttaaaa ttcataaagt gggatgcttc 120 tttaatttaa atacatttag cttcatgaaa aactcactac acagttcttg ttcaagcatt 180 attgggaaac caccagaggg cactctcacc cagggcttaa tttgaacatc tcgcccaaaa 240 gtgactttta a 251 53 487 DNA Homo sapiens misc_feature (1)..(487) n is a, c, g, or t 53 atatcggcac agcactcagg aaagcctaaa gcttgaagac tccatttatt tatagtgcat 60 cccaatccag atacgtaaca attaacgagt tatttttact ataagcaaag ttgcctaaaa 120 tcatagttga tactaaccat ggttaacaga gctctaaagt ttgacagaaa gtgagattca 180 aatcctttca ctctcatatg ctaaaccttt tgccttactc tgggtcatca gagaaattta 240 ggtgagaatg tatgatgaag tctgtgtttt agattcaatg cagatatatc attgtgggca 300 gaactctttc tggttatatc cagttaagag taaatcaggc tttcagcgng tcgcggtggc 360 ttcacgcctg taatncctag gcactttngg gaggnccgag gcggngcagg ntccacgnag 420 gttcaggnag atcgagacct tncgggntag cacgggggtt ttnaccttgt tgnttcaggc 480 tggttng 487 54 199 DNA Homo sapiens misc_feature (1)..(199) n is a, c, g, or t 54 taaggaaaag nnttaataag taaatatatt tattaaatat aaaaggtaca cagtaaatat 60 aaatgaacta aatgctttag ttaaaagaca ataaaaatta tgaaataaaa atgtatacac 120 ttgaaagtat ttaaaataaa tctaattttc ataatgaatt ttaagcatta aggagttttg 180 taactganta gtggaactc 199 55 470 DNA Homo sapiens misc_feature (1)..(470) n is a, c, g, or t 55 aaatgttaga gggtgcgggg gtgaggactg accacagatt ccctggatag tgtagtggta 60 gatttctcca caggatagcg caattggcaa atcatgcttg gttgtgttag gccaaaatac 120 tagttttgct ttctttacct tttctatctt gatgaaaatg ttgcacattc tatagttgca 180 aaacacataa aaggggactt aacatttcac gttgtatctt acttgcagtg aatgcaaggg 240 ttacttttct ctggggacct cccccatcac ccaggttcct actctgggct cccgattccc 300 atggctccca aaccatgccg catggttttg gttaatgaaa cccagtagct aaccccactg 360 tgcttncaca tgccgggcnt aaaatgggtg atatnacagg tcttattatc ccctattggg 420 atttatncct caaaccnctt aaaaacaaac agtggccttt tggccctttg 470 56 384 DNA Homo sapiens misc_feature (1)..(384) n is a, c, g, or t 56 gattaagaac gtaagctcct ttattattat tattattatt attantcatn ccctgttatt 60 taccccnaaa caacagcata actcaaataa taatgacaca cacgtcccgc ccatatacac 120 aataccacta gcctatctgt caggctatct ggcctttgct tggttcctga tggagctgtc 180 tggagacact cnccnctgta aaaatcccgn cttaaacaca ggggacagaa gaaagggggg 240 acctaggtca gatcataaac tgacaggctc ccagcgtcct tagggagtgc taatgtggga 300 gactttgagg acgtgcttgg acacattctg gggcagangg cagnaggcac tgtttgtttt 360 tatgtggntg atggggtaaa ttcc 384 57 449 DNA Homo sapiens misc_feature (1)..(449) n is a, c, g, or t 57 gttcnntttt ccttnctcat ttnattttaa agttttatta tgaaaacaca tggaattaac 60 ggtgttatcc atgtatttgc aacagcagag aaagagtgag agtggaccat ccccatagga 120 ncnacttatc ctttggctaa actaatataa ataatggaaa taacacctaa tacaataata 180 cagcacataa aagagattac attaagagaa gagacaggaa ctgcggagag gagtcctgag 240 tatggaggag atgcggctca tggagaagca tccaggctca ggtgaccttc cctgaagact 300 tcctgtctct gagcagctca gttcagttcc agggtcatac acgtactccg ggacccgggn 360 ctcactgggg ggtcagcgca gacttgcttg cctcttttgg gtttgggaat accacagctg 420 ggctngggga gcagaggntg ctgggtttc 449 58 372 DNA Homo sapiens misc_feature (1)..(372) n is a, c, g, or t 58 ctgagaggaa ctcctcactc agctagcttc aggagccatg acatcatctc taccatggaa 60 attccactca ctctcctgtg cccccacatt tgtcctaggc ctcagagtcc ctataaagag 120 agattcccaa ctcagtatca gcacaggaca cagctaggtt ctgaagcttc tgagttctgc 180 agcctcacct ctgagaaaac ctctttgcca ccaataccat gaagctctgc gtgactgtcc 240 tgtctctcct cgtgctagta gctgccttct gctctctagc actctcagca ccaatgggct 300 cagaccctcc caccgcctgc tgcttttctt acaccgtgag gaagcttcct cgcaactttg 360 tggtagatta nt 372 59 382 DNA Homo sapiens misc_feature (1)..(382) n is a, c, g, or t 59 agctctgcta aaaactccag cgcaatttga tgctgatgaa cttcgtgctg ccatgaaggg 60 ccttggaact gatgaagata ctctaattga gattttggca tcaagaacta acaaagaaat 120 cagagacatt aacagggtct acagagagga actgaagaga gatctggcca aagacataac 180 ctcagacaca tctggagatt ttcggaacgc tttgctttct cttgctaagg gtgaccgatc 240 tgaggacttt ggngtgaatg aagacttggc tgattcagat gccagggcct tgtatgaagc 300 aggaganagg agaaagggga cagacgtaan cgtgttccaa taccatcctt accaccagaa 360 gctatccaca acttcgcaga gt 382 60 373 DNA Homo sapiens misc_feature (1)..(373) n is a, c, g, or t 60 tcttgtgacg tcattttatt ttcagctaca tagacatctt tctcatgtat tgttactaga 60 acaacttgta tagggtttta tggtttgggg aaaacatttt taaaaaatgg acttatctct 120 attatacaga gttataatat aaaaatgatt taaaggctat atttttcagc atgtaggtag 180 ctacactgta atcctgttga aganactttc ctatttaagc ttataggatg anaatatata 240 attaaagtct tctgatcata gcttgagacc atcaagggan tgtttagttt cctccacaaa 300 gagccaccag ggtttttctc ataatctcct ttgggtttca tccagggatg gcttngcaaa 360 ggggagttac cat 373 61 362 DNA Homo sapiens 61 aattaaagca aatagactgt tgtaggtacc aattctcaat gtcacagtgt tacatggaaa 60 gtaaaataca caagaacagc ccaaaagatg gaaacaatgg acgtggtcaa atgacatcag 120 tacaacatcc atatggtcct aagtagccat ctttaaaatg ggttaggaaa tgccttcaat 180 cattcacaca ggacacatgc attggaacaa actctaagga agtgttctta cacggggaaa 240 aggcaagtta caggatgcat ggggcatgga tatggggtgt aggatgtgtg gtatggtggc 300 atccccactt catacacaaa ataccccggc atcggcccac atggcctgct gtgtgcggta 360 gg 362 62 378 DNA Homo sapiens misc_feature (1)..(378) n is a, c, g, or t 62 taaaaaatga tcgttatgta ggtgattgag aagtaaatgt attctttttt aaggtaaaaa 60 tttggaccct tatcatgcat acccccctct gtgctcttca aatcaacatc attattaata 120 tctgtacatt tttgctcatc tgagccagca caggctgagg ctgtcagaat ggacaccttt 180 tggttgttgg gtttctgtca gtttctgggg tgaagctgcg tgattgagaa cgtagctctt 240 gggctgccat ctcggggatt attaaggact gtgaactcta tccacaagcc atggcaatat 300 ctgtcccacc gaatgctncc tctaaacaca ctcttacttc ccgtggatgt gttgttaagg 360 ggtnccgatt ganggctg 378 63 319 DNA Homo sapiens misc_feature (1)..(319) n is a, c, g, or t 63 atgggtcata tttttgttca ctgaaaggac caaccagttt catcaaacaa gctttagaga 60 aagagaaact gagtaattca tcttgtcagt tacagttcac atatatgcac acacatacaa 120 actggctcag catcagtgaa acataactat tcaaatacaa aagtataana aacctcttta 180 aaaaaccaat agcagccaaa acagaacatt tgtaaacaaa accacaactn tcagccctgt 240 gcttaaacac agggttctgc attcttttgg aaacattaag gtatatggca ttaanggggg 300 ttntaggncc atctttntc 319 64 552 DNA Homo sapiens misc_feature (1)..(552) n is a, c, g, or t 64 gctttatcat catgaaacaa gtcatcagag tctttgaatc ttgcgtagga attggaagtc 60 ggggtatacc aggataggtt ttcagcacca ggtgtggcac tcaccctccg gtatgcttgg 120 cagagtttgt gaagcggctc cggtactgcg aatacctagg gaagtatttc tgtgactgct 180 gccactcata tgcagagtcg tgcatccctg cccgaatcct gatgatgtgg gacttcaaga 240 agtactacgt cagcaatttc tccaaacagc tgctcgacag catatgggca ccagcccatt 300 ttcaatttgc tgagcatcgg ccaaagcctg tattgcgaaa gccaaggagc tgggacagag 360 ttgaaggaaa ttcaggaggc agctcttcca tnttcaagga ggttgtttga agacngttag 420 gttttgtaaa cagtgcattt anagggngtt tcggaggcag gtggccgggn acatttngat 480 tgatgnagtt ccacctgttc ttccctttga gggacngggt caggatcagg aaaggggttg 540 ttggcaaact ac 552 65 508 DNA Homo sapiens misc_feature (1)..(508) n is a, c, g, or t 65 nttcggcaca gacttttttt aagctaccaa ttgtgccgag aaaagcattt tagcaattta 60 tacaatatca tccagtacct taaaccctga ttgtgtatat tcatatattt tggatacgca 120 ccccccaact cccaatactg gctctgtctg agtaagaaac agaatcctct ggaacttgag 180 gaagtgaaca tttcggtgac ttccgcatca ggaaggctag agttacccag agcatcaggc 240 cgccacaagt gcctgctttt aggagaccga agtccgcaga acctgcctgt gtcccagctt 300 ggaggcctgg gtcctgggaa ctgagccggg gccctcactg gccttccttc caggggatgg 360 atcaacaggg gcagtgtggt cttccgaatg tctgggaagc tgatgggagc tcagantttc 420 cactgtcaag aaagaggcag ttaggagggg tttgggtggg gcttgttcac ctggggggcc 480 ttccaggtag ggcccttttt aagtggga 508 66 372 DNA Homo sapiens misc_feature (1)..(372) n is a, c, g, or t 66 gtgggnctgt gttgaaacag gccacgtaaa gcaactctct aaaggtcaaa ccaccataga 60 tttgaatctg ctggtcattc gccatctgga tttttaactg aatgaatctc atgggtttaa 120 ccaaacatgc atgtaatcct gaataccatg anttaaatgc gganttgccc agggacgagg 180 aaaccttcaa gaaacaaggt caaagggaca ncagatataa ctgtcacant aaacanttct 240 gttgacgtgg gaaatgcaca tgacttggtt gaaacaaagc tcctcagtgg gccagtgaca 300 tccngggttt ttcttagggt aggctgagga ctcaggggct tatctcacct tctcaggaat 360 gctttttgaa gg 372 67 436 DNA Homo sapiens misc_feature (1)..(436) n is a, c, g, or t 67 ttgcttacat gggcatcctt cagcttttaa taatctgaaa aactctattt acccattgtc 60 aatgtgtata aattaatctg agtcaatttt atacaataaa aggtgaactt ttatgcatga 120 aacaataatt taacaagaaa tgtacctgaa gaagaatgtt cattacaaat atagganaca 180 taaatattac caaatattgg caagcactaa aatgttcaga aatataagtc tattacagtt 240 atagctctct caagcaaaaa aacagcagag aaaaacttag tttaccttag gggctattta 300 tttacttagg gatttgttaa aaggtcgaat ggggtcacac agaatactaa gaagagctgt 360 tcacccaggc ctcactaaga actcttcttc attcagtagc tgtatagtaa catgacaact 420 ggctcctacg acccaa 436 68 350 DNA Homo sapiens misc_feature (1)..(350) n is a, c, g, or t 68 attacttgca aattaagtta ccacagactc tggtagtgtn ctaaatngcg ccaaggcntg 60 ggcncacagc ncagtagcag nctggncgnc agggccactg gccnaccagt gacggacatg 120 cacgtggcag atcatgattt ccagcccacg gagccagcat ttgaaccttg tataattaac 180 tttcagttat gatttcccat cgacattttc tttgccctgt ttgtagctga ttgttgtgtt 240 ttataaatct tctgttaagg cagaagggtg attatgagtg gttcacagca gcccttataa 300 gctgggccag aaaatttcac tagggtcagt aatttaaacc ttggttcttc 350 69 370 DNA Homo sapiens misc_feature (1)..(370) n is a, c, g, or t 69 gtttttttag cacttgttaa tccgttatga tttattagct gtacagcagt agatcctcct 60 ccccagcttt caaccccatt acatatttta ttacaggtct catgttggcg tcctaaaata 120 atgaaaaata tcacacagta cagctaagta caaaatgcat caacctagag tctgatagct 180 aactgatggc tctcttaaaa gcaatacaca ganganaaaa gtgtttgaaa tcagtaagac 240 tgaggctctc taaaaaacac atttttaaac atgtgacagt tcatgtgnca aggantcact 300 ttttagttgg gttttggctt tcacattatt ttattttttg aggatccagg gtttaaatta 360 ctgacctggt 370 70 453 DNA Homo sapiens misc_feature (1)..(453) n is a, c, g, or t 70 gtcctttgca taatgcatgg caaaatgagc ctaaaaccta tatggccatt ttaattttgc 60 ttttgtaata ataccaagcc cagtttcttt caacttgaga gatgagctat ttattctttt 120 acttaatgaa gatgtaagaa atgatcttct gttctaaaaa aaaaaaaatt tctctgatgt 180 ctcttgaccc tgtagaaaca cattcagttt ctacactgca aaacagaggg atatctgtat 240 ggcttccctc tttccatctt tcctttcctc agggaaagct aggaaaaaga aatcttttct 300 atcacagcag acacaccaaa tctccctaag ttgtaccacc ttaattcctc agaatggcaa 360 ttgtgtatgg ataccaagct acaacttgga taagaaattg gtgattttct tctttnaatt 420 ttcattctcc aattttaaaa acatctattg gcg 453 71 308 DNA Homo sapiens misc_feature (1)..(308) n is a, c, g, or t 71 gtagtgtttt gggcacacct aaggtcgatc tgtgttgtat ttaaaaatct aatttcttta 60 tttgtgtggc cttctagaca aacgaagggg accagaggaa accccctgac agatctctgg 120 atgatcctcc ttgaatcctg ggcagtttgg tctctccttg ntgtgctcct gtggcanaaa 180 ctccctttga ttggttcttt ctttccttcc cagctagact aagcccctca tgggcaggta 240 atgaagattg aaaacttttt tctggtctcc agtgtgagca cattcctcct acatggtaga 300 tgtnccat 308 72 432 DNA Homo sapiens 72 tactactcat aacagtttat ttttactttg tacaaaatac aaaaatgcaa atccaaggag 60 tacagaccag tagtgacagg cacactgcac aacagcaacc ttgtctagca agacaggagt 120 tttttaaatt ttattttagt gaataaatgc attatataaa acaacaacaa caacaacaac 180 aaaaacacaa agaggctaga gatttcaccg tttctacccc caaaataacg cttgctatca 240 agactttgga gggggatggg ggaaaagaat ttaaaaggca aataattttt tttcataaaa 300 agtaaaagct accataaaac attttttttt ctgtcactga ttaaatttct tctgaaaagc 360 cgcacatata gacaaaacaa aacaaaaatt cctgaactgg accaacagcc aatactccca 420 ggggtgttaa cc 432 73 411 DNA Homo sapiens misc_feature (1)..(411) n is a, c, g, or t 73 gccatcatcc cacacatcag caccaagacc atagacagct ggatgagcat catggtgccc 60 aagagggtgc aggtgatcct gcccaagttc acagctgtag cacaaacaga tttgaaggag 120 ccgctgaaag ttcttggcat tactgacatg tttgattcat caaaggcaaa tttttgcaaa 180 aataacaagg tcagaaaacc tccatgtttc tcatatcttg caaaaagcaa aaattgaagt 240 cagtgaagat ggaaccaaag cttcagcagc aacaactgca attctcattg ccaagatcat 300 cgccttccct gggtttatag tagacagaac ctttttctgg ttttccatcc ggncattaat 360 ccctacangg tggctgtgtt attcatgggg caggttaaac aaacccctgg a 411 74 433 DNA Homo sapiens misc_feature (1)..(433) n is a, c, g, or t 74 aaggataaat gctttattct ttctgttaat tcatcgtttt caaatgaatg agataatgcc 60 ctagaaacct ccaaaaggta ccaaggaggt gagtgtgtgt atataatcat aaactcagat 120 ttctatatat ttatatacat tgtggtcatt atttgttttg atggccatat tgtctcattt 180 taggttagtg ggagctcctt aatattgctc ccctgttttt gtgacatgat tcattaatct 240 ttgatagctt ccttgatttc tggagtaaga tggcccaagt ttattttaca tatttcctgc 300 cccagacctg gattcagcta ttctcctaag agcactggtt cttaggaacc agtngagtaa 360 tagtatggag agaccacagt cttggatgtt cattggtaac tactggctac tgagttggca 420 ttacttccag gac 433 75 332 DNA Homo sapiens misc_feature (1)..(332) n is a, c, g, or t 75 taatcctaga ttatctttat ttgttctata atttaatagt atacctataa aataattaca 60 ttatacttat agcttttctt catttataaa caanacaaaa aaattaaata caatttgagc 120 cattataagg taaactttgt acatacgnta accccagaag gagcttcaca ctgcagcata 180 tcatattgct ttcattgcta cacccacaat tgggttcgaa gagagtgtgc tcgtgtttgc 240 attctgtaag ttcttagctt aatccctccc ctatctgtgt gggttccatg ttaataaaat 300 gataggggtt ggctttgcag ctggncagag ac 332 76 480 DNA Homo sapiens misc_feature (1)..(480) n is a, c, g, or t 76 cataatacag ttttatagtt taatggacaa tgtttaacat ggtacctctc aaatctgata 60 tatcttgtgg tgcttacaat ttgccttaca ctttcattta aagttaccct gttctccact 120 caccacatgt ataaaatatc ctattttttc tcttaatgtt ttacaaaccg gtaattttca 180 ctatcagtag cggatctttt tataactcac cctatgttgc ccaaaataca ccaataatat 240 aatgattaga ttaaaaaact tggcatcttt tttaaaaaaa tgtgctttct tttccatgta 300 taagattcta ctataccatt tgtgaatgac accctagtta cataacacct acatatctgc 360 ccctgtgaga atttacctta gtcttctaag actctatctt caacagttag ataagtcaat 420 aaccagagtt ccaagaaaag tagttacttt ttaagaccaa attattggga taactgggtc 480 77 214 DNA Homo sapiens 77 tggatcctat aaacctgtca attctgttcc ttttgaggat ggccacacag acaaccactt 60 acctctttta gaaaataata cacattaaca cctcccgatt gaaggagaaa aactttttgc 120 ctgagacata aaaccttttt ttaataataa aatattgtgc aatatattca aagaaaagaa 180 aacacaaata agcagaaaac atacttattt taaa 214 78 564 DNA Homo sapiens misc_feature (1)..(564) n is a, c, g, or t 78 agcagcacct ttttggcttt ttaatgcttg gcttgcttat atctttgtct gtaaaagaat 60 ctaatagttt aaagcaagaa aaattcctag tctgcaatta aatacgtatg gcaactatgt 120 ggaatactaa tcaaatcttt ggtgtccttt ctaaggtaaa ttcatttttc tacctcagtt 180 caatcttcat tatcatttta cattccactg gaggcccagc tagcacaaca atggccagct 240 cttgcctgaa tcccgaaaat tagacttata taaatgatac ccccagaaag actcggggta 300 atctcaaaac aggagaccaa tttttgatgc tggcttgcat tcttgctttc ttggtcattt 360 tgcttttagt aggccaaagc taatacttct ccagtgggaa tttcagatgg ttggacattg 420 gatgggaaca aagaacatat ttaaggaaaa ttaaatttcc ngggtagtaa agtttataaa 480 ctttggaaat ccntagactg ggcttaaact ttcactgggt aaattcncaa taatggnaac 540 accttggcca aagatgctat atac 564 79 497 DNA Homo sapiens 79 agcatattag tctatcaaat ccaactaccc ttaatgccag tgaatgttaa aagtaaaact 60 ttcttagcac tgacaattta ataagtaaaa ataagtggta ctaagcttac aaaaattagc 120 tgaattgggg aaattgttga taaggccaca agtattaaca tgttatactt gcttgctttg 180 agggtatata gcatcttttg gcaaagtgtt acattattgt gaatttaaca gtgaaagttt 240 aagccagtct aggatttcaa agtttataac tttactacca ggaaattaat ttacttaaat 300 atgttctttg tttccatcaa tgtcaacatc tgaaattcca ctggagaagt attagctttg 360 gcctactaaa agcaaaatga caagaagcaa gaatgcaagc cagcatcaaa aattggtctc 420 ctgttttgag attaccccga gtctttctgg gggtatcatt tatataagtc taattttcgg 480 gattcaggca agagctg 497 80 430 DNA Homo sapiens misc_feature (1)..(430) n is a, c, g, or t 80 ngacagttga ttatttattt gaataaaaaa ttcaattaga tttctatcac acacaataga 60 cacaaacaaa ttaaaggtgg attaggggct aaatacatgc atatacatgt atacacacac 120 atacacacag atatatatgc atatacatat attcacacac ataaacacat acatatattt 180 tttaagggaa aaaaacaata aaattaaaac ttagaagtat atatatgtaa actgtgatct 240 ggtttcaaga ttatgaaagg ctttctaaat agcttaaagt agaaatcaca acagtaaaag 300 ataatctgat tataaataaa aaagagggaa aaccttttta tgtaaagaag accataaaat 360 ttaaaaggca aataataaac tgggggaaat acctggcaaa atatattcat atccnaaata 420 taccaagagt 430 81 425 DNA Homo sapiens misc_feature (1)..(425) n is a, c, g, or t 81 agcttcatta aaatcttggg aaattttaat ttgcattcac cttctctaaa catgaacatg 60 aatctgtaaa gtgatacatt ctttcttgct taagaaatta aagcgtttgg ggatttgagt 120 ttttatactc tttgaaaatt gagtttcttg tgctaaaatc atcattcaca aaatgtcctc 180 tcacctgagg aattccaaca cagcaaattc aatctgaaat aaattgaggc tacatttaag 240 agacgggact tccagctaaa aataggtatt agagagctgt ttttgccaaa aaattgaata 300 cttaacctta ttcttcactc ttgactcatt tgttttgtct cagtntgggt gactggaggg 360 tttcttcttt gtatttncat tctgtatcca tttcttaatg cgattgaatt aganaccatt 420 ttatg 425 82 246 DNA Homo sapiens misc_feature (1)..(246) n is a, c, g, or t 82 tatttaaagc acatttttat tatagatagg ttaagtgtgg tttgctgtgg ctaaagatat 60 atttataatg gatgaacaag cttttctaga taccaagagg tataatattt ttctttcagt 120 attgaactaa catttcnctg ataacaagga gacattgaac tggctgagcc tattttaaat 180 gggaaaagac tttttttttc tggatgttgc tttaaagact ggnaaattaa aaattttaaa 240 gtacca 246 83 442 DNA Homo sapiens misc_feature (1)..(442) n is a, c, g, or t 83 gtcatgtcag taatttattt cagggtctaa caaatattac cacagcagtt tagtctcaaa 60 gtgatacaaa actgaactca gggtggttac tgggtagtcc ctagtccaaa agattaagac 120 acacctctaa tacacacaca ggctgtgttc aaggcctttt ccttcccatc ttctggttct 180 gtctccaccc tttccaactg atagcacttc attggtgtgt gtgatatatg tgattatctt 240 aagctagaaa gtacaacaga aggagaggat ggttgtcact tggggattag acagttgaga 300 ggataggaaa ggagttatat ccaccaatac aagcccttct tcccctccta cttagaaaga 360 gggtgggacc attggcattc cttttctaag aagcccctca gcaaggagtc tgttccaaga 420 gaatataacc cgnactanga ac 442 84 403 DNA Homo sapiens misc_feature (1)..(403) n is a, c, g, or t 84 gagtttgttt gaagcacacc tttaactcag aattgaggtt gactgataaa actcagcttt 60 aagtaaccct ctgggcaagt tctgagcaga gatccagtga gctgaatgtc aggcaccacc 120 tccctggagt ctgtatcagt cacatcagca ttctcctctg attagaatca ggtttcaagg 180 gtcttgttca agagtttatt ctctccttta aagatgccac aataccgtat aaggaatgtc 240 tcttggtccc aactaatcta caataagaga ggagcacgta tagtcagagg gcaagaaaac 300 aaccgcagtt tctaagtttc aggttatatt ctcttgggaa cagactcctt gctggagggg 360 gttcnaggaa aagggaatgn aatgggtcca cctctttcta agt 403 85 279 DNA Homo sapiens misc_feature (1)..(279) n is a, c, g, or t 85 attaaataga atttaatact ttattaaatt ttattaatgt ttacttctac ctgtttagac 60 tatttttaag gaatgtagac atcagtacta ctcgaagtgt ggtcccatat tgatcccata 120 ttgatcaact gtcattggct gatggagaga taagcacata aagtgagcaa acatgcataa 180 acatttagaa atgctgatag taaactgaca gtgccaatgc attcaagtac atgattttgt 240 atttacnaaa agtatccttt tatgaatggg tttagaatt 279 86 656 DNA Homo sapiens misc_feature (1)..(656) n is a, c, g, or t 86 ggcgtgaaac tgntnctcta ctaaaaatac aaaaaatagt ggggcatggt ggcgcattcc 60 tgtaatctca gctactcggg aggctgagac aggagaatca cttgaacccg ggagcagagg 120 ttgcagtgag ccgagactgc accactgcag tccagcctgg gcaacagagc gggactcggt 180 ctcaaaaaaa aaaaaaaatg aataagacag tagtctcacc tccaggaaca taacctagat 240 gnngtanagn cgncgaacgg ntnagcnggt ntgngncnac taatnttnca cagggtaatt 300 gaggcagagt gggactctaa agggtctaag atatttacaa ggggtgctag aggaaagaan 360 gagaatatat agggtccaaa agactttatt ttcttagggg agttttacat catctcccca 420 caggcagaag ccctgggtta tgtgactatg ccagtaattg agtggtttaa tctccagttt 480 agggatatgg ggtatttaac cagtccctgt tgctacagat tgaaaagaca tattctttaa 540 ttttgctaac aattaaaggt gatgtttgat ctccnggagt aacttctcca tcttcagggg 600 gtttccaaat tctggnggga aatncagggg tgttncccat ttttatcatt nggatc 656 87 410 DNA Homo sapiens misc_feature (1)..(410) n is a, c, g, or t 87 cattttaatt cactgaacta tattttttgg tacattaccc ttcaactaaa aaaataaaat 60 taaaacattt ccctattact gatgaaggtt agaatgaaga gaacataagg tatataagta 120 ggaaagaaaa cctatgtagg gacagatgtt aatagttatt aaatcctaag taaaattttc 180 agaacttgga aattaccaaa tccaggagtg gtcagattcc tttatgaagg tagatctgga 240 gctacttagg ccagattttt gtattttagc aaagttcctc agatgattct gacgcacacc 300 tggattataa accactaaac cactgaacta ccccaagaag gttacgtgac ctcccagagc 360 tagaatgtnc cagaaatggt gcaagaattc nattactgga ctcctggccc 410 88 434 DNA Homo sapiens misc_feature (1)..(434) n is a, c, g, or t 88 gaaatcacaa caaactgaat taaacatgaa agaacccaag acatcatgta tcgcatatta 60 gttaatctcc tcagacagta accatgggga agaaatctgg tctaatttat taatctaaaa 120 aaggagaatt gaattctgga aactcctgac aagttattac tcgtctctgg catttgtttc 180 ctcatcttta aaatgaatag gtaggttagt agcccnnnag ngtctnaatn ctttangatg 240 ctatggtttg ccattattta ataaatgaca aatgtactta atgctatact ggaaatgtaa 300 aattgaaaat atgttggaaa aaagattctg tcttataggg taaaaaaagc caccgtgata 360 gaaaaaaaat ctttttgata agcacattaa agttaataga acttactgat attcctggtc 420 tagtgggtat aata 434 89 410 DNA Homo sapiens 89 caggttttta ttatttatta ttattgtttg ttttgagatg caatcttgct ctgtcacgca 60 ggttggtgtg caatggtgcg atcttggctc actacaacct ccgcctcacg ggttcaagca 120 attctcctgc ctcagcctcc caagtagctg ggatgatggg cgtccgcgcc gtgcctgggt 180 aaatttctgc atttttagtc cagatggggt ttcaccatgt tgggcaggct ggtcttgaac 240 tcctgacctc aggtgatccg cctgccttgg ctcccaaagt gctgggatta caggcgtgca 300 acccgcgcct ggccccaaat gtcatgtttt taaataaaaa catagaaaat gatataaagg 360 ttcacagcat catcaagaaa acagttcccc cgtgtcgcgg aggggagatg 410 90 224 DNA Homo sapiens misc_feature (1)..(224) n is a, c, g, or t 90 gcagngggaa cgtcttctca tgctccgtga tgcatgaggg tctgcacaac cactacacgc 60 agaagagcct ctccctgtct ccgggtaaat gagtgcgacg gccggcaagc ccccgctccc 120 cgggctctcg cggtcgcacg aggatgcttg gcacgtaccc cgtgtacata cttcccgggc 180 gcccatcatg gaaataaagc acccagcgct gccctgggcc ctgc 224 91 169 DNA Homo sapiens misc_feature (1)..(169) n is a, c, g, or t 91 aaaataaaga atcagattta ttggggtggt taagtgagat catggatgaa ctgtttactt 60 ctattcagca gtagcctttg tggtcccagg cttctggtgg ccagataatt ccctcaactc 120 catgagcagg tgaccgagga ggactctcac atcctgcatg tgtttnaga 169 92 444 DNA Homo sapiens 92 aagttttgcc actaacttta atgtatcatt aggcaaatta tcctctctga gccaaagaag 60 ggtagtggga ttacgggatc tccaaggatc gttcttctta acattgtctg atggcataat 120 tgtcttatta agatttctag ggagaaatac aaagttaaaa ataaaatcat ataggttaaa 180 attatgtaaa catctggcct agagcctctt gattcaactc acataactaa ccagaccatg 240 ggggccaaca ggtcaaagga cactatgtaa aagacatgac ttagacacat ggagtgagag 300 gagcaacaca ggctcccatg ggtggggact gagctggaag gtcacagtaa tgagtgaact 360 cccccttggg cacactttag tatgatgagt aaagcttccc tggtgacttt agagaatgga 420 tcatgggaac acctttataa gaag 444 93 512 DNA Homo sapiens misc_feature (1)..(512) n is a, c, g, or t 93 ggggatctgc ctgaagcagg gatgggacac naagtccctc cagcttatct ntncacaaca 60 accctttccc tgcaganatg gtttgtatac cacaagccct cttagcacgc aaaagccaaa 120 atctaaagat caaccattta tcctgaacaa caccatttga gaaagaggta accatctttg 180 gttctacatg gtttggagag tatagtggta ggaggggctc cctgattccc ctaaagctat 240 gcacaccaca aggggctctg ctcttctgtc tgggatcttc ttataaagtg ttcccatgat 300 cattctctaa aagtcacaag gaagctttac tcatcatact aagtgtgccc aagggggaag 360 ttcactcatt actgtgacct tccagctcag tccccaccca atgggaagcc tgtgttggtt 420 ctctcactcc atgtgtctaa gtcatgtcct ttacatagtg tcnttgaact ggtgggcccc 480 atggtctggg tagttatgtg agttgaatca aa 512 94 451 DNA Homo sapiens misc_feature (1)..(451) n is a, c, g, or t 94 catgatcatt ctttttaatg tgcaccaaat tagcagtaaa aatagcagca gatggatcag 60 agtggttgtc aataaacctt ttctccccag gttactaata tacaattgcc atgaaaaata 120 aaaaaatata tatatatatt tacacttgac tcatcacctc tgcttaggac cctgtaagca 180 caagatattg ctgaactgct gtatttgcta catatggaac aattagacta gcaataagaa 240 gtagtttatg catgtatgct ggcctacatg natatacccc tttccgcaat tactgaggat 300 tatcaacaaa gtttggtctt ggtcttgtga ttataatncc aatnaaatna catnttaaat 360 ggggatatcn ccgaattntg gttttnataa ttacgtaatt aattccnaag aaattaaata 420 ggtaatatag acccctgtaa aaantaaccn t 451 95 435 DNA Homo sapiens 95 aggaaggcca gagtattaat atccccatct gtgtcttttg ccttccatga acctgggttt 60 tgagccctct cttgtaaaat gggcacagta atattaccta cctcagggag ttgtgaggat 120 taaacatgaa gtgctaagca tagtgcctgg tacaaagaca gtactcaata agtgctacct 180 aaaactagta ttcatagcaa tactgttagg ataaagaatt atcatatatg agatagttcc 240 aaatttttgt ttttttaaaa aaaaaagagt tttataagtt caagataata ttttcttact 300 tcaaagaaac aatctcacaa cgagggaatg gtaagaatca ggagagatta ctaacctggc 360 agaggagcta tcacaatcac aaaggtggtt tttccagggc acggctcatc cattacactc 420 cagatgtgct gaccc 435 96 378 DNA Homo sapiens misc_feature (1)..(378) n is a, c, g, or t 96 tcagtttaca atgcataatg atatgtcttt atttcatcaa cagaaatggt gtctagacaa 60 aattcagtta acactagcaa ttcaattgag tgaaaacttt ttttgcacaa tagtgtattt 120 acaatgagta aatgaagttt caattcatta gttcatagca atgctttttt cccccaaaag 180 gtaaaaattc ttagttacag agaataagca tcaacagcct ttcatttttt acaatnaaaa 240 ccncgggnaa aaccncaatc ccctttggaa aaaaattang ggccaggcct aggacctagg 300 tncaataaaa tggatggcat tggaattaaa tttccattaa tcggcatagg aatcccgngg 360 taaaangttt ggtaggaa 378 97 457 DNA Homo sapiens misc_feature (1)..(457) n is a, c, g, or t 97 atgtctacaa ggttttatta aaattaagtt taacattaat aacacactaa tataaaggta 60 aaatttagct tatctggtat aaaagtcata caggaagcat tagtaaatat aaaatagcgt 120 ttagctttct tttgtctaaa aactaataaa aattggtgct aaaggaagca ttcattttac 180 tagaggatca taaaagttaa agacttaaaa caaactttgg caattaagac agcataccaa 240 gatgcaaatg cctggttgaa atggatcaaa tattccatct gcaggttaaa caaaagcaat 300 tagcatgctt gtgcacatgg caggccagag accctgattg tcccccttcc actaaggtgg 360 tcctccagtc gggccaggca tgggctgcat ggtagctctt ttccaggatt ctatagcctg 420 gagtaataag tcatgccaag ctctctcctg ctatatn 457 98 548 DNA Homo sapiens misc_feature (1)..(548) n is a, c, g, or t 98 tttttttgac tcttatctaa ctttacttcc aaacaatgat ttataaaatg tggaggagag 60 tgggtgtcta tgtcaagcag ccttatgata aggctccgtc atatattgtg cttattcaac 120 aatactggtg ttaatgaggc ctggcctcca aaggacaaag atacagaaac agaaaggttt 180 tcccaggcca gaagtattag tttacatcac aacattaaag cataatacac tgtgggccta 240 aaaattaaac tgcatgtgtt ctagcagcag gaacaacaac aacaacaaca aaatgctttc 300 acatttatat aaaaatgaca aagtaaaaag cagagaacac agtgaaaagt gtctggcagt 360 tcattaaaat acagttgagt tgcttctata gtctcaaacc attattatat tatttgaatg 420 agaaagagta tgaggattta actggctgaa ttccattcct accccttatt cataggggaa 480 taattaccct gatattattt aaaagtgttt gctttacnca aaantaaata accttaaata 540 tttaaaat 548 99 459 DNA Homo sapiens misc_feature (1)..(459) n is a, c, g, or t 99 ttttttccag gaaaaaaatt aaatctttat ttttaaaaat cccacaaatc cataatgaaa 60 tcatcatctg aaaaaaaaga tggtagggaa caaaacgtgg gatacattta aaaggcacta 120 gattcattaa taccagagcc attctggaga tgccatgtaa gaaatctgga gttactctaa 180 atcttcttct tagtggtatc agaactgggg agaagggtcc aagcaaagtg ttgcctttgc 240 cagtgtattc ggatcgaggt tatgaggaag agcccttttc ctttgtcagt gagtttcatg 300 ttggtccacc actccagcgc tgacagctcc ccgatggccc tgtcatcgta tctcaggacc 360 tccttcagga tgtgcgttgt gtgctgccga caggggggcg gcctggctct gacacttgan 420 ttactgtact cacactgggc tatgaagtac acagttaga 459 100 443 DNA Homo sapiens misc_feature (1)..(443) n is a, c, g, or t 100 tcataggccc agctgtgaga tacagtaagt tcaagatgtc agaggccagg ccgncccccc 60 tgctcgggca gcacacaacg cacatcctga aggaggtcct gagatacgat gacagggcca 120 tcggggagct gctcagcgct nggagtggtg gaccaacatg aaactcactg acaaaggaaa 180 agggctcttc ctcataacct cgatccgaat acactggcaa aggcaacact ttgcttggac 240 ccttctcccc agttctgata ccactaagaa gaagatttag agtaactcca gatttcttac 300 atggcatctc cagaatggct ctggtattaa tgaatctagt gccttttaaa tgtatcccac 360 gttttgttcc ctaccatctt ttttttcaga tgatgatttc attatggatt tgtgggattt 420 ttaaaaataa agatttaatt ttt 443 101 337 DNA Homo sapiens misc_feature (1)..(337) n is a, c, g, or t 101 acatttacta gtttattgaa tatgaggttt atccatttag caatgtaagg aaaactttag 60 ttctgtttct cagttatcag gagtgaacat aaaactattc taaaccacaa ttagtttacc 120 agcatagtac aaaataaaat ngacaactaa cgaaataaag caattaaagt aacttatttt 180 tactcataag gttaccataa taataaaaat tcctttaatt ttcaaagcac tcttcatgaa 240 aangtagttg ggggaaaatt actatttgtt ccaangtagg ataaaagggn agggatgcnc 300 ccaanttaaa catttttatt naaaaattaa acccccc 337 102 412 DNA Homo sapiens misc_feature (1)..(412) n is a, c, g, or t 102 gattgaaata ccatcagagg cccaagctct cttttccaga gagcagtggc ttttgtaata 60 attcactatc ttagagtgaa aaaggactag acctgtgtta cataataatc ttggttcaag 120 ctgcccttct gaacaaagat ataaacctag catacattgt aatagataac tggtaaaact 180 gacaactttt acttctcaga ggccatttaa atataatagg aacctactga ccaaacctag 240 tgatacataa aattaaagcc tgtgnacttt ttaaagttgt taatcactat acatatgtat 300 gtgtatatgt gtatacacat atataatttt atgatcaata tcttagatat tttagaaatt 360 ccctttngaa tagtcttggc gtgccgtgga aaaatagaaa atcagggaga ta 412 103 458 DNA Homo sapiens misc_feature (1)..(458) n is a, c, g, or t 103 ataatttatt agatctaaag ccccttcctc cccagcccct gctttcatta aggtatttaa 60 acttgggggt ttcactgctc tcccccatga tggagggagg gagcccccca acctcagtga 120 ggagagcccc gagccggccc cggggaaaga ggggtgcaga gggagttccc ccagatcagt 180 accccccacc cctccccagc tagtagcatg accaggagac ggttaatgag agccaagagg 240 agtacctggt gcacctggtg cggtggtgga gacctggggg gcaggtggat ctggggctgt 300 tcccccccct ccgttttttc caccccacag ttcctcctgg gatctggccc tccagggnaa 360 gtggagcctc cagcccctag gggatgcatg aggggggagg gggtgctgag tgggaggaag 420 agtcaggctc acagctgggg tggcctgggg gtgggggt 458 104 404 DNA Homo sapiens misc_feature (1)..(404) n is a, c, g, or t 104 gtaaaacgct aataatttat tagatctaaa gccccttcct ccccagcccc tgctttcatt 60 aaggtattta aacttggggg tttcactgct ctcccccatg atgganggag ggagcccccc 120 aacctcagtg aggagagccc cgagccggcc ccggggaaag aggggtgcag agggagttcc 180 cccagatcag taccccccac ccctccccag ctagtagcat gaccaagcnt agntttnatg 240 agagccaaga ggagtacctg gtgcacctgg tncggtgntg gaagacctgg ggggcaggtg 300 gatctggggc tgttcccccc cctcccgttt tttccacccc acaagttcct cctgggatct 360 ggccctccag ggaagtggaa gctccagccc ctaggggatg catg 404 105 440 DNA Homo sapiens 105 cagcaacatg aagttggcag ccttcctcct cctgtgatcc tcatcatctt cagcctagag 60 gtacaagagc ttcaggctgc aggagaccgg cttttgggta cctgcgtcga gctctgcaca 120 ggtgactggg actgcaaccc cggagaccac tgtgtcagca atgggtgtgg ccatgagtgt 180 gttgcagggt aaggacaggt aaaaacacca ggccctccct gctttctgaa acgttgttca 240 gtctagatga agagttatct taaggatcat ctttccctaa gatcgtcatc ccttcctgga 300 gttcctatct tccaagatgt gactgtctgg agttccttga ctaggaagat ggatgaaaac 360 agcaagcctg tggatggaga ctacagggga tatgggaggc agggaagagg ggttgttttt 420 ttaataaatc atcattgtta 440 106 447 DNA Homo sapiens 106 cagcaacatg aagttggcag ccttcctcct cctgtgatcc tcatcatctt cagcctagag 60 gtacaagagc ttcaggctgc aggagaccgg cttttgggta cctgcgtcga gctctgcaca 120 ggtgactggg actgcaaccc cggagaccac tgtgtcagca atgggtgtgg ccatgagtgt 180 gttgcagggt aaggacaggt aaaaacacca ggccctccct gctttctgaa acgttgttca 240 gtctagatga agagttatct taaggatcat ctttccctaa gatcgtcatc ccttcctgga 300 gttcctatct tccaagatgt gactgtctgg agttccttga ctaggaagat ggatgaaaac 360 agcaagcctg tggatggaga ctacagggga tatgggaggc agggaagagg ggttgttttt 420 ttaataaatc atcattgtta aaaagca 447 107 373 DNA Homo sapiens misc_feature (1)..(373) n is a, c, g, or t 107 tctgaagtca cagcagcaat acagaacaaa gaatttacct taatctgatc tttttacgtg 60 gaattccctg actcaaactc agtggcttag tttggaaacc tctgaatggc tggggagaga 120 aaatcttttg aaactaagtg aataaattaa cacacacata cgtnggaaat cagcccttgt 180 gcaagtgtaa catgaacatc actgatgaga gtgcagaaac tccaggcacc cctctgcctc 240 ctcctatccc tgggcctggg gttgtaggga gaagtcacac tcaattcatt tctagccaca 300 ccatgtccct aacagtgcta gtgtnaacta gccctgacct gggtattggg tttaaagaat 360 ggagcctcgt gcc 373 108 367 DNA Homo sapiens misc_feature (1)..(367) n is a, c, g, or t 108 gctcattctt taaaccaata cccaggtcag ggctagttca cactagcact gttagggaca 60 tggtgtggct agaaatgaat tgagtgtgac ttctccctac aaccccaggc ccagggatag 120 gaggaggcag aggggtgcct ggagtttctg cactctcatc agtgatgttc atgttacact 180 tgcacaaggg ctgatttcca cgtatgtgtg tgttaattta ttcacttagt ttcaaaagat 240 tttctctccc cagccattca gaaggtttcc aaactaagcc actgagtttg agtcagggaa 300 ttccaccgta aaaaagatca cgattaaggt aaattctttg ttctgtattg ctgctgtgac 360 ttcngna 367 109 523 DNA Homo sapiens misc_feature (1)..(523) n is a, c, g, or t 109 ttgttttgtt ttctttcaca gatttaatac cgcgatctca gccaaactcc ggccgagaag 60 ttgagaaatg tcttcacccc ctctcgacat tcgttcgtgc ttcttcgcct tggtggagcg 120 ataggggcga gcaggggtgg ggccggctgg tgctgctacg agggccgtgc agcgnttnaa 180 taagtgacat aaaatgtcta cacgcataag taaccgtact tagggcttct gcaagggcca 240 ccagagcgcc taaggtggca agtgggcccc gtgtcacngg ccgcgctgca ggcgcttgcg 300 caaagtcttc cacgcagccg tccagcccca tgcgctccag ggccgcgtaa acggctccga 360 ggcccgcggg ttgctgctgg cgccaggctt tgagcatctc gtactgctgg tctcggaaac 420 ggccgatttc cancttcaag ggcttcgatc tctgcctcgc gaagcccagc gtgccaacga 480 acttcttcca agcgccgnct gggaacngcg tcaatcaagg tcg 523 110 372 DNA Homo sapiens misc_feature (1)..(372) n is a, c, g, or t 110 cacaagccct ggttactgca gatgaagctg ggatggaggc tctgacccca ccaccggcca 60 cccatctgtc acccttggac agcgcccaca cccttctagc acctcctgac agcagtgaga 120 agatctgcac cgtccagttg gtgggtaaca gctggacccc tggctacccc gagacccagg 180 aggcgctctg ccgcangtga catggtcctg ggacagttgc ccagcagant cttggccccg 240 ctgctgcgcc cacactctcg ccagagtccc cagccggctc gccagccaat gantgctgca 300 gccgggcccg cagctctacg acgtgaatgg acgcggtccc aagcgcggcg ctggaaagga 360 agttccgtgc gc 372 111 454 DNA Homo sapiens misc_feature (1)..(454) n is a, c, g, or t 111 caatttttaa aaatgtttta ttacaaagct tcttttaaaa aaatgctcag cacattaact 60 caaactggaa tgacaaacgt taggatgaca gttttgggca aaggctgtgc ttgctttttt 120 aaaaaatggg tacatcaatg ctcattttaa caactnggca taaaatccca ctaattggct 180 aataaaaaca gatacaaata cagaacattt aaagtaataa caattcaagt gctgggcttt 240 ttacaacaag ggggtgataa ggaaagaaat gaaaattcac tgcaaaccag tctgctgaac 300 gcatctgtta aggtttactg tttaaaaaaa aaaaagaaga aaacagaaga aaaaataaac 360 tgaaattagg gctgccaatt gctaccaaca gagtgggttt ggctattaca tttatttagc 420 tctactggaa caccttacaa gggcggagaa gcca 454 112 452 DNA Homo sapiens misc_feature (1)..(452) n is a, c, g, or t 112 acttgaattt ttttaattta cactttttag ttttaatttt cttgtatatt ttgctagcta 60 tgagctttta aataaaattg aaagttctgg aaaagtttga aataatgaca taaaaagaag 120 ccttcttttt ctgagacagc ttgtctggta agtggcttct ctgtgaattg cctgtaacac 180 atagtggctt ctccgccctt gtaaggtgtt cagtagagct aaataaatgt aatagccaaa 240 cccactctgt tggtagcaat tggcagccct atttcagttt attttttctt ctgttttctt 300 cttntttttt tttaaacagt aaaccttaac agatgcgttc agcagactgg tttgcagtga 360 attttcattt ctttccttat cacccccttg ttgtaaaaag cccagcactt gaattgttat 420 tactttaaat ggttctgtaa ttggtatcng gc 452 113 459 DNA Homo sapiens 113 ttttttttcg gtatttgaat acatttattg tgacaagaat gctgttataa atattcataa 60 gcaaaggcca tctttttatc taggaattgt caaagagaag attccaaatt ggaaggatac 120 atcttttgta aaatctgcca ccaattcctg ctttgagaat aagcacctat tgtaaaattt 180 ctactaacat tataaatggt cacagcacat gccacttgat acaatccaaa ctttgaaatg 240 tttgacttct cagtgggctg tccctctcca ctgcaacccc ccttcctcca gcctcctgaa 300 acatcgcact atcctttcgg taagcaattc catatagata gctgggggga ggaggagtat 360 aacctggacc atagcatcag gttacatcag gtacatttat ttctaaagtc taatagagaa 420 cagtttttac tgcttaatag taagaagcac tgagagtga 459 114 395 DNA Homo sapiens misc_feature (1)..(395) n is a, c, g, or t 114 gtatcctgcc cagtgttgtt tgtaaataag agatttggag cactctgagt ttaccatttg 60 taataaagta tataattttt ttatgttttg tttctgaaaa ttccagaaag gatatttaag 120 aaaatacaat aaactattgg aaagtactcc cctaacctct tttctgcatc atctgtagat 180 actagctatc taggtggagt tgaaagagtt aagaatgtcg attaaaatca ctctcagtgc 240 ttcttactat taagcagtaa aaactgttct ctattagact ttaagaaata aaatgtacct 300 gatgtacctg aatgctatgg tcaggttata cctcctccct cccccaagct atctatatgg 360 gaatttgctt accaaangga tagtgccgat gtttc 395 115 154 DNA Homo sapiens misc_feature (1)..(154) n is a, c, g, or t 115 ggtgtaatta gcatnggtca atgcgggacg atngagtggc tctggaaacc tgatggattt 60 cctcgatgag ccgttccctg atgtggggac gtatgaggac ttccacacca tcgactggct 120 aagggaaaag tcacgggaca ccgacagaca catg 154 116 214 DNA Homo sapiens misc_feature (1)..(214) n is a, c, g, or t 116 taaatgacac agtcagtgtt tttctgaaaa taattgccac cttgttgcta attaaacatg 60 atggattcgg ggtcctggtt tgccatctgg gccatatgtc tcagaacatc cttttttgtg 120 atgatgccaa gaagtctccn gctcgggtca caaggaattg cngaaggccc cagttttccg 180 ggangatatn caacaacggt ttcaatcgga attt 214 117 256 DNA Homo sapiens misc_feature (1)..(256) n is a, c, g, or t 117 tttaagctag aaaaaggcca aaaagcaaaa cctgagaaaa caatacgtgt tgttttctca 60 ggaaaagaaa aaccttcatg accctactga agagcattgg agatcagctt ccgctaagat 120 gctagcttgg ccaagtctgt tatattcacc tgaaaaagtc ttagcagaga atttttgcat 180 tcccacccaa aagccctctc agccactcaa atgcctatct tctccagtct acaagttaca 240 tgntcccacc cagcat 256 118 260 DNA Homo sapiens 118 accgaagctt aaagtaggac aaccatggag ccttcctgtg gcaggagaga caacaaagcg 60 ctattatcct aaggtcaaga gaagtgtcag cctcacctga tttttattag taatgaggac 120 ttgcctcaac tccctctttc tggagtgaag catccgaaga atgcttgaag tacccctggg 180 cttctcttaa catttaagca agctgttttt atagcagctc ttaataataa agcccaaatc 240 tcaagcggtg cttgaagtcc 260 119 435 DNA Homo sapiens misc_feature (1)..(435) n is a, c, g, or t 119 taagaggttg cgaacataca tatttattta taatacaaaa tnaagattng agggaaaagt 60 gctttaaaaa gtancatgta agtgtataaa tgaaattntn gcttcttctc cgatacaatt 120 ttgattgggt gagcattatt tgcttttaca ataatgcttt attttgtttt ttgcattgca 180 ttgcactaac ctgtccatta atacaaacag aaaaagaagg tggaggacgt gcccagccgc 240 gtggtcagcg tgccgaacct cgcctcctat gcaaagaact ttctgagtgg cgatctgagt 300 tccaggatta atgcccctcc aataactaca tcacccagct tggacccaag ccccagctgt 360 nggcctggac cctacaaacc canaccagtc tacagattgc aaaaactgcc acaaggtttt 420 ggggggaatg tttgg 435 120 417 DNA Homo sapiens misc_feature (1)..(417) n is a, c, g, or t 120 aagatttttg tnccaagtcc ngtgctaagc acatcctatg gattaattcc tttagtctca 60 cgtcagtctg atgagatagg tgctgtatta tcttaatttt aaaggcaagg tatatggaga 120 cctggagagg tcaagtgacc tgtccaaggc cacagagcta agaatgagga agactgtaat 180 ttgaattcag acctccaggc cagatggagt ccaccttttg tataacccat gctgaagttt 240 tcaggtaagt gattcagtgt cccttgtcta atcatccatg aaaaaaggcc ttctggaatt 300 tggtaccagg tgctagaaag aatcctactt cccctctnat ctacanngna aanacgnata 360 agggcccctg tccccaacat cccccaaacc ttgtggcagt ttttgcatct gtagact 417 121 442 DNA Homo sapiens misc_feature (1)..(442) n is a, c, g, or t 121 ctatcattgt gaactttttc ctctcctgat ccagttcatc atggaggctc atcatttctg 60 tttccaaagt caagtttcgc tgttctaagc tctttatcct ggactcatac tctatcttct 120 gtttggtcat ttcctgtttc aggctggaaa ctaaactgtg cagtgcntgt ggttgctgct 180 gctgttgccc acaaatgtct cactgttgtc actgctactg gtggcacgac tacttcgacc 240 tcccacactc ctgtggtcac ttttgctttc atagtccctt ggggtgggaa aggtcgtcct 300 gcgggggccc atccaaaaca gggtcctcaa agttcccccc aaaaaagtct tgctctgggc 360 aggtggtggt agaagagcga caggagttgg agttctcagg gagggagatt tcacaggagg 420 aagtggacca ggtagcactg na 442 122 477 DNA Homo sapiens misc_feature (1)..(477) n is a, c, g, or t 122 tttttttttc acaattggaa tgtgctttat ttcagggaaa tataaaggga aatgaatgct 60 attataactt ggtagaacag aagaaatggc tacctagctt tgctttccaa ctacaaacat 120 aaatgaggat ctcagcattt aaggtaaaac atgataagca caaaaggaga gttcactggg 180 gactggactc cctcatttac tctagaaatt atgagaacca gcagcaatat tcctcaagca 240 tccatctcaa catcaagttc ctttgtttta tttaccagat gaccagggaa tcataggatg 300 agtttgggct gcaactgtgt cttccactgc cattcccaaa gacttgaaca cggtgggtct 360 tctcacagtg gggctgggtt cacttccctt aatcactttt tcccaggttc aggcaaaggn 420 tcttggggcc cctggaccag gcaggggaca ttttccagga ttnctttcag ggggcag 477 123 97 DNA Homo sapiens misc_feature (1)..(97) n is a, c, g, or t 123 ncgcagctcc agnctcctca tcccgcctct agagacgncc ctggcaagct tntncagcgg 60 tcccgaagng ggggtnatgc agcccgtgcg cancgtg 97 124 430 DNA Homo sapiens misc_feature (1)..(430) n is a, c, g, or t 124 actgaggtta gaaggcacag gtggcgagat gagccgggta ccagcgttcc tgagcgcggc 60 cgaggtggag gaacacctcc gcagctccag cctcctcatc ccgcctctag agacggccct 120 ggcaacttct ccagcggtcc cgaagagggg tcatgcagcc cgtgcgcacc gtggtccggt 180 gaccaagcac aggggctacc tgggggtcat gcccgcctac agtgctgcag aggatgcact 240 gaccaccaag ttggtcacct tctacgagga ccgcggcatc accttcggtc gtcccttccc 300 accagggtaa ttgtggttac tcttttgagc ccagcaatgg gcaccntgct nggcggtcat 360 gggatgggaa atgttcataa attgcaaaga gaacagttgc attttttgcc ntttgccacc 420 aatttttttg 430 125 394 DNA Homo sapiens 125 aaaaacagac atagtctcac tgttgtccag attggagtac agtgacacaa tcatagctca 60 ctgcagcctc aaactaatgg gatcaagtga tcctcctgcc tcagcctccc aagtagctaa 120 gcctactgga tgcactacta tgcccagctc acacagaagg tttctgagta atctgttgct 180 ctttttccct acaatttgtc ttccatataa ctcaaactga caaggctatg gcttacataa 240 agaaatatat tataaatcaa caacactcat gataagttta cataagacat gagaatacac 300 ctgaatcacc aaccgggaaa aatgattgaa gagcttgaaa ttaagcctaa gtgtaagtct 360 ctgttaagct tacaacatta caatagttaa atcg 394 126 392 DNA Homo sapiens misc_feature (1)..(392) n is a, c, g, or t 126 tctaaccttc gatttaacta ttgtaatgtt gtaagcttaa cagagactta cacttaggct 60 taatttcaag ctcttcaatc atttttcccg gttggtgatt caggtgtatt ctcatgtctt 120 atgtaaactt atcatgagtg ttgttgattt ataatatatt tctttatgta agccatagcc 180 ttgtcagttt gagttatatg gaagacaaat tgtagggaaa aagagcaaca gattactcag 240 aaaccttctg tgtgagctgg gcatagtagt gcatgccagt agncttagct acttgggagg 300 ctgaggcagg aggatcactt gatcccatta gtttgaggct gcagtgagct atgattgtgt 360 cactgtactc caatctggac aacagtgaga ct 392 127 452 DNA Homo sapiens 127 gatcattcca tcatgtattg atgcatacaa atatcacatt gtaccatata aattatacaa 60 ttattgtaca aatatataca tcaatataca attgtacata caatacatac aattgttgta 120 caaatatata caattattac ttgtcaatta aaaattttaa aaaagaaatc tgaaataaca 180 gttgccccct atgagcatct cacgataaat ccctttaatc tcctctacat atactgagta 240 ttaaaaaaca gaatcgtcta gaacattgtt gctgttctga gacctgtctt tctcatttaa 300 cacaagtgaa catttttctt tgtcagcaag tagcggtaaa catcatccat tctaatggct 360 gtatttttta ataggtggag ttgtatcttc agggcagatt cctaacagtg gaatggctgg 420 gtcacaaggg aaatgtgtag gtagtttttg ga 452 128 470 DNA Homo sapiens misc_feature (1)..(470) n is a, c, g, or t 128 gtgacaagca accttaaaag agacacaagg agactggcag acagaggaag aagaggcagc 60 aatgtgaccc cggangtgga aatctcagtg atggggccag gaatgtcaag gaatggtcaa 120 ggaatggcta cagcaccaga aaaagaggca aagtgaggct tctcccctag aatctctagg 180 agcgctccag ccctgctgat gtctagattt ttggagttct ggcctccaga atgtgagaga 240 gtaaactatt gtttaaagct accaagtttg tggtaacttg ttagagcagc cacaggaatg 300 aatgtacagg gaatcagggc agtctcatac actgatggtg ggaaaacaaa ccggcacaac 360 ccttatggtg ggaaatttga caacattgta caaaaactac ctacacattt cccttgtgac 420 ccagccattc cactgtttag gaatctgccc tgaagataca actccaccta 470 129 476 DNA Homo sapiens misc_feature (1)..(476) n is a, c, g, or t 129 tttttttttt tagtctaaag aaagttctga acagaatatc aattaagctt acatcacaaa 60 aactttaaat gtatttacag agtgaataag ttacatagat aaactctgaa tatgtttctg 120 cagtgcaaca agttcacatg cacacatcta acacttgaca gcattaagtt taaggagaga 180 acttaagaat ggccctttac atatatatta cacataaaat atgacatcga agaaacaaag 240 taacaactca tattttacct ttatgattct acttctgact atccaaacag gatattaaaa 300 tatggcatgc ctggacaggg tgaaaagact tggggattta tcttgtggaa tagttttctc 360 tacaaaacgg gcaaagttta attaaattta acncttcatt ccttccggcg gtttnaaata 420 tggctcntta aaggcnacct tctggttaaa aggccggccc ggttcccttn aaaagg 476 130 408 DNA Homo sapiens misc_feature (1)..(408) n is a, c, g, or t 130 gccacactct cttngcttgc aaattgtaag gcaacatttg cagggggatc aagagatgga 60 gtaattacct gtcaaccagg ggactccgaa gaaaagcaaa tggaatctct tgcacaattg 120 gaactgtgtc agagattata taagctacac ttccagctgc tattgctttt tcagtcctac 180 tgtaagctca tcggccaggg tgcacgaagt tagctccatg ccagagctgc tgaatatgtc 240 caggggaact gagtgaccta aagaaacacc tgaaggaagc cagtgcagtc attgcagctg 300 accctctcta tttcagacgg cgcgtnggtc cgagcccacc tttcacgtnc actgaagcag 360 gccatccagt tccatgcttg ggagttgcct tgaagggacc aacggact 408 131 329 DNA Homo sapiens misc_feature (1)..(329) n is a, c, g, or t 131 gaagtaaaag atttttattg ttctatagac acttctgaaa agagatctaa ttgagaaaat 60 atacaaagca tttaagagtt tcatccccag agactgactg aaggcgttac agccctcctc 120 tccaaggctc agggctgaga acggttagca tatcgaatga tcagtaaaaa catgcaaaag 180 tgagaaggaa agggaaaaag gtgcattccc ctaagctgag ggggatggaa tttcagaaca 240 gaggangcag ggtggacaag taccaaggtg gctctccctt tccctctgtg tnatctttca 300 aaaccanttc caagcntgga tnaaagcaa 329 132 384 DNA Homo sapiens misc_feature (1)..(384) n is a, c, g, or t 132 tttttttttt agcacaccac agccaccata cagacaggag tgcagcccct cctccctagg 60 aacccccacc cctactcttc actaggcagg gcccatggct catgaatgca gaacagtcac 120 cccagccatg gctgagcata cccactgtta gtgacacaga gtttccctga gaagaggctc 180 ccaaaggcat acgacagccc cttggccact gccacagtaa cagtgctatc cctcctgccc 240 ttggantagg ggaggacaca aagagcctaa gggctacact tcaaacttag gagtacatca 300 cagccaccat atgggagagg agaccaacct cttcctccct gtgaggcctt tcaactncct 360 gctccccaac aaacagaacc ccaa 384 133 66 DNA Homo sapiens misc_feature (1)..(66) n is a, c, g, or t 133 cagtactgcg gccnncnctc ctntccnaac ctcgctctcg cggcctacct ttanccgccc 60 gcctgc 66 134 387 DNA Homo sapiens misc_feature (1)..(387) n is a, c, g, or t 134 attgaaaata gatgttttat tttgtttata caaggtacaa tgtcaaaata caaataatat 60 ataatgtata gatataatag acaaggaagt ataaatataa acgcatatat tcgtaaaatg 120 gcactgagtt gagttttctt cttcctgaat ccttcaatgg agaggattcn ctgggctcag 180 catctctccc acctttccca ggtccctgtc catgtgtgca gagagctgga gacagggtgg 240 ttagaagccc aaacgctggt gtcttccctg tagacgtctc ccacgccagg agaagccttg 300 taattgacag agagctttgg gtatgtcact tttctctgtg aactgaaagt ttaggatgag 360 ggcncggaan attcggggca gggtttt 387 135 188 DNA Homo sapiens misc_feature (1)..(188) n is a, c, g, or t 135 acnagcatcc gcctcccacc agccgccagt gtngtatcca cagggccaca gcgacaccac 60 tgtggctatc tccacgtcca ctgtcctgct gtgtnggctg agcgctgtgt ctctcctggc 120 atgctacctc aagtcaaggc aaactccccc gctggccagc gtttgaaatg gaagccatgg 180 aggctctg 188 136 410 DNA Homo sapiens misc_feature (1)..(410) n is a, c, g, or t 136 ccttcttgtt cactnggtgt ggtttattct tgaagcaagg tctctctcca gttgaagccc 60 ccagttggtc catgggtaag aggaaggatt ggtggatctg tcagctgcca tattccagtt 120 tctcctaatt cttcacagga acaaaatccc agatatggga tctttcggac catttgtacg 180 aagtccttgg agttctgagg tgacaggccc tgaagttggc aggtacacgc ttcaagggaa 240 gatgcgtggg ccacaatcag gatgttattt cctttacttt tacattcact tattattnct 300 tttgttactt gggaaacttc tactngatat aagtatcata ggattctgga aacaactaat 360 ttngctcgat tggaatgtga ggnctggtag gttgtatcaa cactcaggtt 410 137 176 DNA Homo sapiens misc_feature (1)..(176) n is a, c, g, or t 137 cnttcggcac gatggggagt attggagagg cggccttatg angnccangn gctcggggag 60 acgactcctc ttactatcat ctgccagccc atgcagccgc tgagggtcaa canccanccc 120 ggcccccaga agcgatgcct ttttgtgtgt cggcatggtg agaggatgga tgttgt 176 138 503 DNA Homo sapiens misc_feature (1)..(503) n is a, c, g, or t 138 tttttttttt tcttcctttt ttttctttta gaaatattca aattttaaaa caacaattaa 60 gtggattatg ggaacaggaa aaccatctta ctttggttcc aggatatact ggtaatatag 120 ctaaggatgt agatgcttat ttattacagt tacattgaga gatttcatct actaaagagc 180 atttggtttt tcaaaacatc cctgaactgt ataatttaca aaaaaaaaaa gtctcgtctg 240 agaactgtga actgtggaag aaatcaaaac tatttttnct tttaaaaagc cacgtaatga 300 aaccnctaat gaaatcccag caatctgctt cacattgaag tggaaaaata tccaaaagga 360 gcagcttcaa ttttcattga ggtgaaagtg cactatgaag attgttcacc tttggctgca 420 tttgggagtt atatggttat ttggtaacnt taagaactnc tggattttta atgccatccn 480 ggcatnaaaa tatnatttnt acc 503 139 563 DNA Homo sapiens misc_feature (1)..(563) n is a, c, g, or t 139 taataaaaca caatcttaaa aaagttaatg atgattggtc ttggtggttc ctagtggtaa 60 gtcctgtctt attttttcac atagtataaa ttatattttt atgcaggatt gcattaaaat 120 ccagtagttc ttaatgttac caaataacca tataactccc aaatgcagca aaggtgaaca 180 atcttcatag tgcactttca cctcaatgaa attgaagctg ctccttttgg atatttttcc 240 acttcaatgt gaagcagatt gctgggattt cattagtggt ttcattacgt ggctttttaa 300 aagaaaaaat agttttgatt tcttccacag ttcacagttc tcagaccgag actttttttt 360 tttgtaaatt atacagttca gggatgtttt gaaaaaccaa atgctcttta gtagatgaaa 420 tccctcaatg gtaactggaa atanataagc atccacatcc ctagcnatat taccnggtat 480 atccnggaac ccaagtaaga tgggtttccc ggtccccata atccncctaa atggtggttt 540 aaaaattgga ntattcccaa agg 563 140 429 DNA Homo sapiens misc_feature (1)..(429) n is a, c, g, or t 140 tttttttttt aaatgaatgt aacaagcatt tattaaaaac tgtgctgcac aaaacatgtt 60 agaaactaga ccaggtgcta ggagtctaat caaggcaggg gcagggtaaa aacatgggaa 120 tattacatgg acaagcttgt ctagcatggc agtctataac ccttgagggt ttacataaaa 180 taaaggaaca tttttgtggn ctcaggctcc ccagagttct ctttatgttt gggcagagac 240 tgcccatccc ttagtgatcc caccttagag ccaggttttc aaagtcattt ctcccagtat 300 atctgtctct gtatgcaagt ttcctctggt tgccttgagc aaaaacaatc atccaagtca 360 aatttgctag ccctatgctg ggccagccca cgtttcccgt aggacatctg tagggtaagt 420 tnagccccg 429 141 499 DNA Homo sapiens misc_feature (1)..(499) n is a, c, g, or t 141 ttccagaagg caaaaagaca ttaccatgag taataagggg gctccaggac tccctctaag 60 tggaatagcc tccctgtaac tccagctctg ctccgtatgc caagaggaga ctttaattct 120 cttactgctt cttttcactt cagagcacac ttatgggcca agccaggctt aatggctcat 180 gacctggaaa taaaatttag gaccaatacc tcctccagat cagattcttc tcttaatttc 240 atagattgtg ttttttttta aatagacctc tcaatttctg gaaaactgcc ttttatctgc 300 ccagaattct aagctggtgc cccactgaat cttgtgtacc tgtgactaaa caactacctc 360 ctcagtctgg gtgggactta tgtatttatg accttatagt gttaatatct tgaaacatag 420 gaggatctat gttactgtaa ntagtgtgat tactatggtc tagagaaaag tctacccctg 480 ctaaggagtt ctcatcccn 499 142 575 DNA Homo sapiens misc_feature (1)..(575) n is a, c, g, or t 142 gcttttaaca atgatgattt attaaaagaa acaacccctc ttccctgcct cccatatccc 60 ctgtagtctc catccacagg cttgctgttt tcatccatct tcctagtcaa ggaactccag 120 acagtcacat cttggaagat aggaactcca ggaagggatg acgatcttag ggaaagatga 180 tccttaagat aactcttcat ctgtccttac cctgcaacac actcatggcc acacccattg 240 ctgacacagt ggtctccggg gttgcagtcc cagtcacctg tgcagagctc gacgcaggta 300 cccaaaagcc ggtctcctgc agcctgaagc tcttgtacct ctaggcttga agatgatgag 360 gattcacagg aggaggaagg ctgccaactt catgttgctg ttggaaggct ttggaaaaac 420 acagcagggc tgagagcagc tgaaatttat accttccanc cgctgagctg gnatgcnagg 480 ccaggggtgg gactagggga ctgcagacac cttaagncct ggccagaaac ttgacatttc 540 tngagattag caccaccctg tgtaccctgg gtctt 575 143 568 DNA Homo sapiens misc_feature (1)..(568) n is a, c, g, or t 143 aggacccagg gtacacaggg tgggtggcta ttctccagaa atgtcagttt ctgggcaggg 60 cttaggtgtc tgcagtccct agtcccaccc ctggccttgc attccagctc agcgngtgga 120 aggtataaat ttcagctgct ctcagccctg ctgtgttttt ccaaagcctt ccaacagcaa 180 catgaagttg gcagccttcc tcctcctgtg atcctcatca tcttcagcct agaggtacaa 240 gagcttcagg ctgcaggaag accggctttt gggtacctgc gtcgagctct gcacaggtga 300 ctgggactgc aaccccggag accactgtgt cagcaatggg tgtggccatg agtgtgttgc 360 agggtaagga cagatgaaga gttatcttaa ggatcatctt tccctaagat cgtcatccct 420 tcctggagtt cctatcttcc aagatgtgac tgtctggagt tccttgacta ggaagatgga 480 tgaaaacagc aagcctgtgg atggagacta cagggggata ttggaagcaa ggaagagggg 540 ttgttctttt aataaatcat cattgtta 568 144 130 DNA Homo sapiens 144 aaattggttt taattttttt taattggatc tatcttcttc cttaacattt cagttggagt 60 atgtagcatt tagcaccact ggctcaatgc gctcacctag gtgagagtgt gaccaaatct 120 taaagcatta 130 145 151 DNA Homo sapiens misc_feature (1)..(151) n is a, c, g, or t 145 agaaattgac gacttcacac tatggacagc ttttcccaag atgtcaaaac aagactcctc 60 atcatgataa ggctcttacc cccttttaat ttgtccttgc ttatgcctgc ctctttcgct 120 tggcaggatg atgctgtcat tagtantttt t 151 146 400 DNA Homo sapiens misc_feature (1)..(400) n is a, c, g, or t 146 tttttttttt ttttttgatt aacattcttt atttcacagt atttttgatc agaagtctta 60 gaaatcatga ttcatctggt tacaaatccc atgagtttct ctttgaatga acctcttgct 120 tccagtccca tacaacgcat ctcccaccag ccccagtggg ttgtaactgt gattcaacac 180 tgagtgctcg cttggaaagg aggtggagct caacttccaa ctcagagggc ctctcccact 240 gctctcaggg aaatgcccat gattcactta tgctgtatca acaacaagtg cagctgggcg 300 ctgcctttcc cagctgggcc aagcggctcc taggggggaa tctccaccct caggagggct 360 tagggaaagg ggaaggtntg aacgagttca ggggcccngg 400 147 478 DNA Homo sapiens misc_feature (1)..(478) n is a, c, g, or t 147 ctcaaagggc tgtcaccatc acctgctgct aggacactac aaaacaatca aataattctt 60 ttctgtaatc caatatgcag caagcaaggg tgacctccag tggcccactc aagtccatga 120 gccattatct aggatacttt ctctctcttt catgcagttc aaagcccagg tatctctcag 180 atctgctgcc tgagaaataa gctcctttat cagttagctg ttttatcatt aggatacaag 240 acagcccagt gtcatcaaca gtgagcaaat ctgggcatgg tgtttgtctc gtacagttgg 300 ggatagggag gccattcatt cccatggggg cacagcttaa cattatcccc cagtggatta 360 cttttcgatt acacttgaag gaggaccacc ttgtctttta aaggttcant ttccnggggg 420 ttggcantgt ttccaaccca gttgtttncc agctgtttca caaccagtgt gntggatt 478 148 444 DNA Homo sapiens misc_feature (1)..(444) n is a, c, g, or t 148 ttttttttca ccttaggcag ctttttattt tgcatccttt ttttcaactt tgtcttctat 60 tagctgtnaa gaaatacatg tctgctaaag ttacacgatc ttcgcacaac agcaacctac 120 acattagtct acaaagggga acaaacccaa attcctcaga agtctgagtc cactgttgcc 180 ttctttctgg ccatctggag gttacaatat agcacagaat gactatgcaa gttaaatatt 240 catcttagac atggacattt gctttgggac tcctaaagtg gagtcaaatt tgatctctac 300 agaaactcta caatgtagca gagcactgtg cgtacttatt gactcccggg acaagccgga 360 aaccccggaa tttgtcattt ctatcaggtt tttatataaa ttggttctta cctacttatt 420 gatggcttac aatttgggcc attn 444 149 450 DNA Homo sapiens misc_feature (1)..(450) n is a, c, g, or t 149 ttttagggtg aatcctatgt gtagaattgc ttggtcaaat ggtaagcaat aaaagcaata 60 aacagttgac gcccttgatt cgtttttctg ttcaaatgtc aattctttaa agaggccttt 120 tctgatgact catgtgaaaa acagctcact gtcattctct ggctctttac tctgctttat 180 tttcctttga agtccttatt ggacatcata ttatctatta atttgcttat tgtttatctt 240 ttctactgga ctgtacacct catgtgtgta gggcatttgt tttgctcaca gctgtcaggt 300 attggggata ccccaatatc taacacagta aacaatcaag aattattggg ttgaattaat 360 gagttaataa aattaaatac tggcctcatt gaaggggtta tatagatttt taaaaaatac 420 cnggttttgt gcnccatgga cccaaactgg 450 150 399 DNA Homo sapiens misc_feature (1)..(399) n is a, c, g, or t 150 tattgccatc taatgctcag aacacacttg tattgcaaga aaatattttt ttgcttgttt 60 ttttgagaca tagtcttgct ctgttgccca ggctggagtg cagtggtgat cttggctcac 120 tacaacctcc gtctcccgag ttcaagtgat tctggagcct cccaagtagc tgggactaca 180 gatgcatgcc accatgccca gctaattttt gtatttttag cagagatggg gtttcactat 240 attggccagg ctggtctcaa actcctgacc tcgtgaatcc acccaccttt ggcctcccaa 300 aagtgccaga gattaccagg catgaagcca ctgcacctgg gcctcaagaa naattatata 360 tcacgtggaa tagggatngt agtctctgca ctgatttng 399 151 426 DNA Homo sapiens misc_feature (1)..(426) n is a, c, g, or t 151 agactgcacg tggttcttag agcctacagt ggctgacaga gtattgggta ttaacgttaa 60 cggatcctgt gatgtggcgg tgantgcagc tgtgatccac gaagtctctg aacagggctt 120 agaaactgac tgcactttgt ttttaacagg agcctacgtg aagaagagag cacacaattt 180 taaaagttga ttttatattc tctgagtttt tcttcttgct tcaacaaaac tctaggaaat 240 gccataagct gaaagaacat gaccttcctc agacatctct tctctccctt tccaaacaca 300 actaggagtc atttttttat tggtgctatg ccattaagag gtcttcctgc ttacgctttc 360 ctcagagcgg attgttggct gggcgcagtg gctcagtgcc tgatatccca gcactttgga 420 aggccg 426 152 305 DNA Homo sapiens misc_feature (1)..(305) n is a, c, g, or t 152 gcatatgact tggaattggc ctgtaccaaa ctctgggacc tgctgttcct ggatccagtg 60 gtcttgttcc aacagatgaa tctataaaat ataccatata caatagtact ggcattcaga 120 ttggagccta caattatatg gagattggtg ggaccgagtt catcactact agacagcaca 180 aatacgaact tcaaagaaga gccaagctgc ctaagtacca agctatcttt gataatacca 240 ctagtctgac cggatnaaca nctggaccca atcagggaaa atctgggaaa gcacttggaa 300 aaact 305 153 275 DNA Homo sapiens 153 atattataaa agcattttat tgaacacatt ctggaggtag ttagaaccaa aacaaaattt 60 gggattgggg tggggattct gttttgatga tttagatttg ggaaaacttt gggttctcgt 120 gtcagcaggg gccatgctgt gggaaacctg aaggctgatt tgaagcagaa tatagaactg 180 cggcacggga gaccaggggc tgggaatggg gctctcctgg gaaccaaaga atgtggttct 240 gcaattggct tggtctagac tactctccag aaaag 275 154 246 DNA Homo sapiens 154 cagcgtcaaa tttgtctcca ccacctcctc ctcccggaag agcttcaaga gctaagaacc 60 tgctgcaagt cactgccttc caagtgcagc aacccagccc atggagattg cctcttctag 120 gcagttgctc aagccatgtt ttatcctttt ctggagagta gtctagacca agccaattgc 180 agaaccacat tctttggttc ccaggagagc cccattccca gcccctggtc tcccgtgccg 240 cagttc 246 155 342 DNA Homo sapiens 155 ttaaaaaaat tttttttatt gaagaacagc atacataaag acacaccagt tttaagtgca 60 caacccattt ctcacaaagt agacacactt gagtttccac caccaggtga agagataaag 120 ccttattagc acctcaaaag atcctcccct tgtgcccctt ttcccattac ccaccctcct 180 ccccaaaggt aaccactatc ctgacaccat aggttagttt ttgcctgttt ttaaacttca 240 caaaaatgga atcatacagt ctgcattctt taatgtctgg ctcctttcgc tcaacatcat 300 gtttgtgaga ttcatccagg ttgcctgtag cagcagttca tt 342 156 269 DNA Homo sapiens 156 taagcccagc actttaggag accaaggtgg gaggatcact tgagcccaag agttcaagac 60 cagcctgggc agtgtggcaa gacccaatct ctcattaaat aaataataat aaccaaacaa 120 aaaaataacc accacttttc acactcacca tggcaaaatt taaaaaccta acaattccaa 180 gtgttgtcaa ggctatagga caactgctgg tgagagtgca aattggtata accactgtga 240 aaaaaaagtt tggcattatg tatgaaact 269 157 466 DNA Homo sapiens 157 aaattttgag tgacttgagt ctcttgcagt ccctgattac acagaacctt tctgggctac 60 ttggagcatc acgaatagtc tttcctgtac ttaccagatt tcaagtattc ataacttgac 120 tccctaagtg tacaagttgg gaatagtaca gggccaagtt caagtcgcat atgctgtact 180 gttcctcctg caaatgtggg gaaagaagag ggagatacta gaggaactga ggctccaccc 240 attcattcag ttgctctaag caccagagga cttgtttcag aaaaggggag tgggaacgcc 300 ctccgacttt gccctcctcc ggagcatctc tgggacgcag ggagtctggc tagcgttaat 360 aggaaaggtt gctcggcaga gtggccctgg agtactgact tgtctctccc tcctttgtca 420 aggtccatgt ttttctggct cttcctgcac actcatccct agatta 466 158 522 DNA Homo sapiens misc_feature (1)..(522) n is a, c, g, or t 158 gacaccaatt catagcattt attgacattt ccatttaaaa tgctaggaaa gctgtatnaa 60 ttgtaaacat ggaaaccaaa tacttgcata aattatttca aaaactctac agcacattag 120 aaaacagtgc agctattgaa ggatagaaac ataaaaccga caaatagaag ggaggggccg 180 attattaaat cgtataccca tactgagatt tcagtgcctg tttgaggacc agcaaaccat 240 gattgtcaag tttaagttgc agtattgatg ccacagttgg cctcaatttg ctctgcacat 300 ttcgtacatt aacgctcata atctagggat gagtgtgcag gaagagccag aaaaacatgg 360 accttgacaa aggagggaga gacaagtcag tactccaggg cagctctgcc gaagcaacct 420 ttcctattaa cgctagccag actccctgcg tcccagagat gctccggagn ggggcaaagt 480 cgagggcgtt cccactcccc cttttcctga aaccaagtcc tn 522 159 506 DNA Homo sapiens 159 tgaggattca tattgtcatt ttacttattt acagaatcaa taaaccaaca catacacact 60 attcagagag gtgggaagtg ctctgcaacc ttctccctca aacctgggcc cagaccccag 120 tcctggacca ctgcatccac ccagcaggaa aggggtccag ccaagacttt tcctgacttt 180 gtaacttaca gacacaagag aatagagggt agaagggaaa ttcttggcac ctggactaga 240 gtgagataaa aggagagtag gaaaccagtg ataggagaga agtgagggag gtacatacag 300 ttttataaat aactagacaa ggtctgagca ctttgggtgg ggatggagtg agaaaggcta 360 caggcatgta ggggcctaag tggaaaagga agaaatagtg cttggggcca gagcggatga 420 gagatcagct ctgggccttc ttttgcccca tctgtaaacc agtggttgcc taggtggtgt 480 caaacagccc gtcccggtta tctagg 506 160 553 DNA Homo sapiens 160 ctctggctat ggggatagga ggagagctcc ggaggtctct gacccctccc aaggatcatg 60 ccgcagcccc actgacccag gagtaggggc ctaagggcag ggaacctgga actgggctgt 120 gtgttctgca agaaattgga gccggtggca cggcatatga ggatgctggc ctggaagggg 180 acttcagaag ctacggggca gcagaccact atgggcctga ccccactaag gcccggcctg 240 catcctcatt tgcccacatc cccaactaca gcaacttctc ctctcaggcc atcaaccctg 300 gcttccttga tagtggcacc atcaggggtg tgtcagggat tggggtgacc tgttcattgc 360 cctgtatgac tatgaggctc gaactgagga tgacgtcacc ttcaccaagg gcgagaagtt 420 ccacatcttg aacaatacct gaagtgactg gtgggaggct cggtctctca gctccggaaa 480 aactggctgc attcccagca ctacgtggcc cctgtgactc aacaagctga gaatggtatt 540 tggaaaattg gga 553 161 409 DNA Homo sapiens 161 gtttattcta cttttatttc acatatataa aaacagctta taattgtact gaacacaaaa 60 tacaaacaaa tacattttat tgcacataaa aatattttaa atgaagtatt gaagtattgc 120 acgtaataga attgatttag gaaagtcaca aacctattat aagactagta ttattctagg 180 tctgaagatt acagaatatt tcctaataga gatttgccac atcacatatt gcacattttc 240 caacactatt ctatgtcttg caaatattcc tcatagtctt tgcttatgtc ttttctctgt 300 aagacactgt ataaaagatt ataaaggcaa agaaatatgt accatcgaaa aggacctgtc 360 tacagctgag gaagtaaaaa aataaataca cgatcatccc attcttttg 409 162 360 DNA Homo sapiens 162 acagctcttt gcatccggag agtggacaag aaaatgatgc caccagtccc catttctcaa 60 cacgtcatga agggtccttc caagttcctg tcctgtgtgc tgtaatgaat gtggtcttca 120 tcaccatttt aatcatagct ctcattgcct tatcagtggg ccaatacaat tgtccaggcc 180 aatacacatt ctcaatgcca tcagacagcc atgtttcttc atgctctgag gactgggttg 240 gctaccagag gaaatgctac tttatttcta ctgtgaagag gagctggact tcagccaaaa 300 tgcctgttcc tgacattgtg ctaatcctgc tgcaatgatc ctgaaaaggg cattgacttt 360 163 395 DNA Homo sapiens 163 tttttttttt tttttttttt tttttttttt tttttttttt tcaactgaag ttctatttat 60 ttgtgagact gtaagttaca tgaaggcagc agaatattgt gccccatgct tctttacccc 120 tcacaatcct tgccacagtg tggggcagtg gatgggtgct tagtaagtac ttaataaact 180 gtggtgcttt ttttggcctg tctttggatt gttaaaaaac agagagggat gcttggatgt 240 aaaactgaac ttcagagcat gaaaatcaca ctgtcttctg atatctgcag ggacagagca 300 ttggggtggg ggtaaggtgc actgtttgaa aagtaaacga taaaatgtgg attaaagtgc 360 ccagcacaaa gcagatcctc aataaacatt tcatt 395 164 354 DNA Homo sapiens 164 cagacactgt atctttagat tgatgtcgac cacaaagttc agccagagct tgaggctaga 60 tgcacagcct tgctattggg aagaaggcct tttctagctg tacaacacag tctcactggg 120 cattcatcca gaaatagaga agaaagtctg ccagacttga gttatgttgt cttttattag 180 cagggaatgt catcacagat tggatagtac atccaggtgc aatgtcacca tcagcaaggt 240 cagcttgaca ctcaagtgga agattaggga agaatgacta ggataaaaaa aaaaggaggg 300 caccaaggga aagggatgat ggggtgagct ggcgagtgtg ggtgggaaat gaaa 354 165 348 DNA Homo sapiens 165 aaaaagacaa agaaacttta tttatacaaa actccacccc ttctgttcca ctctcctcag 60 caaacacaga taacaggtga tgaaactaaa acacacagac gagcattact caacccaagg 120 ttcccgcctt ccctagcacc tgaggtctgg gccaacatgc agggtaactg gtgccttatg 180 cctgctgtct ggattgcccg gcccacaggg tggctgagca tatttattct gggggttcca 240 tgcatacgag gagcccccag ccatacagct gggcatgggt gtttggcagc aaattgtccc 300 tgctttagtc acagcaattt ttcatgtcct ctgtttgctc cccttaaa 348 166 437 DNA Homo sapiens 166 ccagtccctg tccccttgtt cacctttgga ctggacaggg agccacctcg cagtccgcag 60 agctcacatc tcccaagcag gccccagaca cctgggtctg gagcaggggg aaaaggtaga 120 ggacatgcca aagcccccac ttccccagga gcaggccaca gacccccttg tggacagcct 180 gggcagtggc attgtctact cagcccttac ctgccacctg tgcggccacc tgaaacagtg 240 tcatggccag gaggatggtg gccagacccc tgtcatggcc agtccttgct gtggctgctg 300 ctgtggagac aggtcctcgc cccctacaac ccccctggag gccccagacc cctctccagg 360 tggggttcca ctggaggcca gtctgtgtcc ggcctccctg gcaccctcgg gcatctcagg 420 aagagtaatc ctcatca 437 167 421 DNA Homo sapiens 167 cagattctaa caagaatact tttattatac acgtatcata cacacaacaa ttatttgggg 60 aacatttaca ggcagagagt tcaattccaa atctccattt cacccacaca cactgtactg 120 cacactcacc ttagggttca gcccaacagg aacgagacaa agttattgct ttctgaacag 180 agagtttcaa ttaaatagaa tcttccaagc caagaacaga gcccagcatc ctcttaattc 240 ttaataccct gtatatatat gaataaaacc ttatgatgtg ttatagatta ccccatcacc 300 attaaaagtt aatattaaaa ttggatccca tgtctcaaaa aagtcgtaag aagtgcacca 360 gtatttacag accccattaa attacgcata aataaaatct gtacactcaa cgcactgttt 420 c 421 168 461 DNA Homo sapiens 168 cctgattgtc atagacaaat cctacatgaa ccctggagac cagagtccag ctgattctaa 60 caaaaccctg gagaaaatgg agaaacacag gaaataaaat tggaacgaag aaaggttagg 120 agagtaggga aggaacagga ctgcaaaaat ccttctccac cgcacagact gggaacccct 180 cctggcctgg gggaagagtt tgttacctac cttactattt aaagagcctt cactggttct 240 gcatcacccg cccctggact tcttagttgt ttctctagcg ctgagctatc tcctaacttt 300 ggacctatta tcagaaggtg acaagtactg gctctttatt cattaagctt tttttttttg 360 aaccccattc tttccttctc tgaaagtggt gctataagtt ttagaatctt ttaaatacat 420 tccctgggcc aacagaccca cacacttagc cattgaaatg t 461 169 487 DNA Homo sapiens 169 tttttttttg catttgtaac atgcacattt attcagaaca aacaactcat taatttattc 60 caaaataatt tcacttgata acttgaaata cagagtaaaa caaattggtc aggtaaatat 120 acatgtaact taaaaagaaa cagtcatgta ctttaggcat aaggacaatg cttttctctt 180 ttacaaattc ttagttaggt caaattctct ggaagtcact acatttcttt actgtgatgt 240 gttttgggtg aagttacaac ctatttgcaa atcacatcac tggtttgtcc aagcagaggt 300 agatgagagg taagctcctc tcctgctaaa agtctcctaa aaacagcaag aaaatatttt 360 tatgtgttca aaaatgctca tttatttata ttcctaaatt ttcttttact cagtataata 420 tagataattt aaaagtaagt agaatatttt tattatatat gttttatttt tatacttcta 480 gttaaat 487 170 434 DNA Homo sapiens 170 ggactcacgg gcggggcatg atggtggtgg gtacgggcac ctcgctggcg ctctcctccc 60 tcctgtccct gctgctcttt gctgggatgc agatgtacag ccgtcagctg gcctccaccg 120 agtggctcac catccagggc ggcctgcttg gttcgggtct cttcgtgttc tcgctcactg 180 ccttcaataa tctggagaat cttgtctttg gcaaaggatt ccaagcaaag atcttccctg 240 agattctcct gtgcctcctg ttggctctct ttgcatctgg cctcatccac cgagtctgtg 300 tcaccacctg cttcatcttc tccatggttg gtctgtacta catcaacaag atctcctcca 360 ccctgtacca ggcagcagct ccagtcctca caccagccaa ggtcacaggc aagagcaaga 420 agagaaactg accc 434 171 376 DNA Homo sapiens 171 ttgcagtgga gatggggttt catcatgttg cccaggctag ttttcctttc tatatacaga 60 aaaatttaaa gtgaatgtga tgttggagag agtgggaagg aaaagtaatg gcaagtatgc 120 ttgctcatta ccaggcactg tgctaagctc tgtgaataca cagataagta aaatccacgc 180 tgtttctcaa agaactcaca atctgtttaa gaagcagatg tctatacaat aattttataa 240 ctattattca atgtgattag tactcacata gctctatata gagtgttata gaagaataaa 300 ttagagaata tctcattttt cctccagtgg tttaaaaaga tgtcacagaa actgaattgt 360 aaatggtacg gaaata 376 172 439 DNA Homo sapiens 172 ggagataagt tgccttgatt ctgacatttg gcccagcctg tactggtgtg ccgcaatgag 60 agtcaatctc tattgacagc ctgcttcaga ttttgctttt gttcgttttg ccttctgtcc 120 ttggaacagt catatctcaa gttcaaaggc caaaacctga gaagcggtgg gctaagatag 180 gtcctactgc aaaccacccc tccatatttc cgtaccattt acaattcagt ttctgtgaca 240 tctttttaaa ccactggagg aaaaatgaga tattctctaa tttattcttc tataacactc 300 tatatagagc tatgtgagta ctaatcacat tgaataatag ttataaaatt attgtataga 360 catctgcttc ttaaacagat tgtgagttct ttgagaaaca gcgtggattt tacttatctg 420 tgtattcaca gagcttagc 439 173 390 DNA Homo sapiens 173 tttttttttt tatatgtaat gactgtagta accagtttat tacacagatt aatcattctt 60 gaaagtacaa gctccagagg agaatctggg tctttaaata tacacaagta tttccatcaa 120 atgaattttc acccttacat ccaaatagac ctaagcggtt aaaaacataa gaaaaataag 180 agctattagc tatgtattaa ctgagaaacc acatacaaac caaagaatat ggaagagaga 240 aagaagggct gaaaggccaa aggttgaagg ggtagggaga tgtaaaagag ttgggaacaa 300 agcccatcac acttgatgta ctaatagctc caatccattt aaatgttgac cagttaaact 360 tagaccttaa aatgcaggat gtgggtagag 390 174 476 DNA Homo sapiens misc_feature (1)..(476) n is a, c, g, or t 174 gagattgctc ggatctacaa aacagataga gaaaagtaca acagaatagc tcgggaatgg 60 actcagaagt atgcgatgta attaaagaaa ttattggata acctctacaa ataaagatag 120 gggaactctg aaagagaaag tccttttgat ttccatttga ctgctttcta tgagcccacg 180 cctcatcttc ccctgtgcac atgtttacct gatacagcag tgctgcgtgt tgtacatact 240 tggaacaaca aactagaaat actgtacttc tgtaccaaca ttgcctccta gcagagaagt 300 gtgtgtgtga caagccagtt ctacaggcat tacctaggtg tgagactaaa agcttttctt 360 attgacttaa atttggataa cagcaaggtg tgaggggggt ggtgggtatg gtgtgtgctt 420 ggatgggaaa gaanaggctc cactcaccta taggagatta tttttaagtg gaatcc 476 175 243 DNA Homo sapiens 175 gcgccgcgcg cccgaaaggc tgcggccgtg ggcccgtccc gcagaccctg tggttgggct 60 gaccccgctt cagggtgccg tacacgaaga ctagggccat ccgggcagac tgtaacttgt 120 ttcttcaagg aagtgttgcc ttagaatcca gatccacagt aagcctgaga gtcttaaaaa 180 cttttgactt cagaatcctt ccacatgatt caagaaaaag ttaagtccac ttcacagggt 240 gac 243 176 273 DNA Homo sapiens 176 gaaaactgga tatttggtcc ccatggactt tctggtcacc ctgtgaagtg gacttaactt 60 tttcttgaat catgtggaag gattctgaag tcaaaagttt ttaagactct caggcttact 120 gtggatctgg attctaaggc aacacttcct tgaagaaaca agcttacagc tctgcccgga 180 tggccctagt cttcgtgtac ggcaccctga agcggggtca gcccaaccac agggtcctgc 240 gggacggcgc ccacggctcc gcagcctttc ggg 273 177 471 DNA Homo sapiens 177 tttgcccagc aaagacaaat atatttgtcc ctgttgctac aataggaagt taacaatctg 60 gcaagatatc tgaacacaag caaatgaaaa cagttcacct aacacccatg caaattataa 120 atttcctccc atatacaaaa tgatgagaaa taacagcaaa aatgtatact ttcttatttt 180 tgaactttta aagttctagt ttggtctttg aatcaaaaca aagtaaaaga tgtttataaa 240 agccatttcc ttttctttcc ccactatgct catttgactt gctcttcccc ctatagggta 300 ccctgagtca ttcagagaag gagaattaat agcactgagt tggtgatgaa gctcctgtta 360 ggacatatgg cttcacaaaa agaaatactt ccagataagt cagagagaca gttggacgtc 420 ttgagcaaat cttgaaagag atagggaaga aagcagaagt tgttgggtgg t 471 178 341 DNA Homo sapiens 178 gtgctcccac tttgacaatg atgaaattaa aaggctgggc aggaggttta agaagttgga 60 cttggacaaa tcagggtctc tgagcgtgga ggagttcatg tccctgccgg agctgcgcca 120 caacccgttg gtgcggcgag tgatcgacgt cttcgacacc gacggtgatg gagaagtgga 180 cttcaaggaa ttcatcccgg ggacctccca gttcagcgtc aagggcgacg aggagcagaa 240 gttgaggttt gcgttcagca tttacgacat ggataaagat ggctacattt ccaacgggga 300 gctcttccag gtgctgaaga tgatggtggg caacaacctg a 341 179 506 DNA Homo sapiens 179 ttttgcagtt acaacattta ccactttatt ataaaggcta caactcagaa acagccaaat 60 ggaagacatg tataggacaa agaaagatgt gggggtggaa gaggttgtat ggagcctcca 120 tgccctctct ggatgccatt ggttgactgg gggaattaat tccctggtgc ttccagcctg 180 caagatgagc tccttcaacc agcaagtccc cagtcaaaag agtgcacggg gtgtagctgg 240 aagttgagca gatggtagtt tgcatggatg agataaagcc ccaggggaca gggcagctac 300 acatgaatcc aaatagtcta atctccaaaa ggaacagaga gtggattcat acaacatacc 360 aagcccgccc cctaaatgca tcccactcag gtcacttata aagctccaag gatgggccaa 420 gaacacaagc tctacaccag ggaaacttgg aggcatcaga aggacagaat aagacccagg 480 ttcatagggg atgaaaaatc gaacag 506 180 411 DNA Homo sapiens 180 caacaatagc gggaatgaag actgtgcgga atttagtggc agtggctgga acgacaatcg 60 atgtgacgtt gacaattact ggatctgcaa aaagcccgca gcctgcttca gagacgaata 120 gtagtttccc tgctagcctc agcctccatt gtggtatagc agaacttcac ccacttgtaa 180 gccagcgctt cttctctcca tccttggacc ttcacaaatg ccctgagacg gttctctgtt 240 cgatttttca tcccctatga acctgggtct tattctgtcc ttctgatgcc tccaagtttc 300 cctggtgtag agcttgtgtt cttggcccat ccttggagct ttataagtga cctgagtggg 360 atgcatttag ggggcgggct tggtatgttg tatgaatcca ctctctgtgc c 411 181 232 DNA Homo sapiens 181 ttttattatt aaatgtatat ttttaataaa gccaatagtt attttactta taggagcttt 60 aaaagataca aaatgtagag ttccagtttg gaagcattgt aactatacac acaatgtcct 120 gctgatgccc tagcaaggca cccacgccca accatgcaaa ggacacacac gttcacacat 180 gcacacacat gcgctttggc gagacccctc tgccaagcgc acaccctgga at 232 182 183 DNA Homo sapiens 182 ggacttagaa gccttacaaa tacatctgtg cattcttgct tcagacttta caactgaggg 60 ccagcccagt ctggaagcat ctcttattaa tgttacaagg aaaccgctac ctcagcaaac 120 aaaaggaatg gaggaggaga cttacaactg ttttgtatat agacattttc aggcacgtgc 180 ttt 183 183 429 DNA Homo sapiens 183 tttttttttt tctgcttcaa tataatttta ttagcagtta ttacatcaaa attcacattt 60 agaggatcca gaggactgtc ttagaaaatt ctaaagcata tttaattagg ttttaacagt 120 aagggagaac ttaatataac acagccctta aaaagtcaag actactactg aaaattaagt 180 gcagttctat caagaactag aaatgaactg cacgtgtagt gtcacttaaa gcaaagcttc 240 atgaaaatat aatacacttc tatgaatgta tcagtggcaa acatcattgg cttccaaaaa 300 actgacacta aaggaatttc caatcaaaac acaagcacag tggctttcat tcaatataga 360 gctatgataa gtctatcaag agaccctgaa tccttacgta cttgtaatat gattttatgc 420 tgtgacact 429 184 312 DNA Homo sapiens 184 tttttttttc actcaataaa tttttattag aaatgcagtt acactgagaa aggatttcac 60 aatggtcaaa tcagtgcaca atactaccta gttttataca ctgaaaaaaa tgtcttgtca 120 ggctacatca ttttagaaga cactttacag cattcttgta gcattagaaa taatgaatag 180 aagagcgtca aggtgaaaac aaacaccaaa tttggtccaa taatactgat tgctctttgt 240 taaaattcct ttgatacagg tactttttat aaatgaatat gaatgaacat tcggttaaaa 300 tgacttactt ga 312 185 288 DNA Homo sapiens 185 gggtgacacc aggcttacct tttaaagttt agtatacgga gacaatttta atggaaataa 60 ctactgtaga ctattgaaga atgatctctt tgtgatttaa gaagtggctg gattggaact 120 tttaatatgc taatgtggaa aattaattac ctttatgaag gtggtttatt acaaataagc 180 acactaaccc ctcggaagtt gttttaccta ctttaaaagt tttaatggat tgcacctctg 240 taaactattc ctaaaatgtg tatgatatat ttgaaaaggc ttccatta 288 186 528 DNA Homo sapiens 186 ttttttttta actgtccgca agttaaaaag atttattgct attccaggct tcaaatgagc 60 ccagaactca gggctggtgt gtgtttcaga agttgttatg atgtaacagg gtggtagaaa 120 aatccaggca gtttgatgtc gaggccaccc tctcttcctt ggacccctgc tccaaaagca 180 gctgctggtg aggctctttc ccatctgcct cattcaccca acaggactcc aagactgagg 240 caggcagcct tgtgatcccc acagctcaca ggtgagaggc tgctcatacc tctcctagca 300 ctggaagagc cttgtccttg ggaccggaca ctatggcttt ggccctgtgg agggagaaac 360 ggtgccacag gagttgtctt aagaggacaa ggcatgcacg gtctgagatc agaggttgtg 420 acgtggccac ccatgagcca gtccgtttgg gacacatcac actgcacagc tttttaaaaa 480 ataattaggc tgcaatcttt taaaatggta agatttcata taccaatc 528 187 466 DNA Homo sapiens 187 aaaaagctgt gcagtgtgat gtgtcccaaa cggactggct catgggtggc cacgtcacaa 60 cctctgatct cagaccgtgc atgccttgtc ctcttaagac aactcctgtg gcaccgtttc 120 tccctccaca gggccaaagc catagtgtcc ggtcccaagg acaaggctct tccagtgcta 180 ggagaggtat gagcagcctc tcacctgtga gctgtgggga tcacaaggct gcctgcctca 240 gtcttggagt cctgttgggt gaatgaggca gatgggaaag agcctcacca gcagctgctt 300 ttggagcagg ggtcccagga agagagggtg ggctcgacat caaactgcct ggatttttct 360 accaccctgt tacatcataa caacttctga aacacacacc agccctgagt tctgggctca 420 tttgaagcct ggaatagcaa taaacctttt tagattgcgg gcagtt 466 188 407 DNA Homo sapiens 188 tttttttttt tttttttttt tttggctttc tgggtctttt atttgtaccc atgtgtctgt 60 cacaccatga atgtacctgg ggaaatcaac tgacctccct gaacatttca cgcagtcagg 120 gaacaggtga ggaaagaaat aaataagtga ttctaatgct gcctaggtca ctctcaaccc 180 ccatttactg gcacagttgg gtggagagaa gggaaggggt atgattgtcc tgatggctca 240 gggatagagg gcatggtaga aagcaaagta cccacacagg ccccagttcc agctgcggag 300 gacacttggg cgctccaggg acaggacttg ctggtacaca gtctgccctt cccgacgcag 360 gcacactgtg aattggtcag cgatgactgt ccggtgctga tacattc 407 189 384 DNA Homo sapiens 189 gaaacaccag ctcatttaag ctttccccaa cgcccggccc tccggacgag tacctaacaa 60 ccaccggcgc ccgcatctgg aataggctgg cgagatactt agtatccgag ggctcgggac 120 ttggcgccat cgaggtcatg gggacccagg atccagggaa catgggaacc ggcgtcccag 180 cctcggagca gataagctgt ccaaagagga tcacaagttt attgccctga agagactggc 240 ggcaccaagg atgtgcaggt tacagactgt aagagtcccg aagacagccg acccccaaaa 300 gagacggact gctgcaatcc ggaggactct gggcagctga tggtttccta tgagggtaaa 360 gctatgggct accaggtgcc tccc 384 190 416 DNA Homo sapiens misc_feature (1)..(416) n is a, c, g, or t 190 tttatttnnt tgaatctatt taattgctca gactgtgcta gagaatacgt accatgaaat 60 acatatattt cataaggttc agttacaaaa tggattgttt caaatggcaa tttcttacac 120 taacctgatt atgaaaaaaa gaagtctgta tcatctgctt ccaagtctgt tatgtccaaa 180 tatattttaa ttatgcattt attttgctac ttttataaat attagagatt tcaccntaaa 240 ttatttttgt aactagttct agaacatgtt tnccaattat tattnnccta atgggagaca 300 tataattgac cnatggttta tggcatatat ggtcctctac acagnggaac ctntttttaa 360 aaggaatagg taaaggaaaa tgcgggacgg cctgggctct ccagggccaa gggcca 416 191 425 DNA Homo sapiens misc_feature (1)..(425) n is a, c, g, or t 191 ttgctccagt ttttcagaag aagtgaagtc aagatgaaga accatttgct tttctgggga 60 gtcctggcgg tttttattaa ggctgttcat gtgaaagccc aagaagatga aaggattgtt 120 cttgttgaca acaaatgtaa gtntgcccgg attacttcca ggatcatccg ttcttccgaa 180 gatcctaatg aggacattnt ggagagaaac atccgaatta ttgttcctct gaacaacagg 240 gagaatatct ctgatcccac ctcaccattg aggaaccaga tttgtgtacc atttgtctga 300 cctctgtaaa aaatgtggat cctacagaag tgggagctgg gataatcagn tagtttactg 360 cttacccagn ggcaatatct gtggatggag gncagtgcta cagagacctg cttacacttt 420 tggac 425 192 360 DNA Homo sapiens 192 gcaacttgaa ttgtattttt tattgaaaag aattcaggct agagttggga ggaggatgca 60 agagctactg ggaaggggga gctcagtctg aacctggggg atcaggggag taggggactc 120 tccccttgtc cactgatggg gggtctggct gttactcctc tcccttcagc acagaaagaa 180 cttggtcagt aaaaatgcct gtgtaagtgc tcatggctgc tgtgcttttg ctgtacaagt 240 ccctgagttt ctcatctaca gcgggcaggt atgtcttctc gtacaggttc tgggcggctg 300 tctttgctga ctcccagtaa ctggagagag attccttcac ctgggtgagg aaggtcgggc 360 193 346 DNA Homo sapiens 193 aatttgaggt ccaggggacc gaacagcccc agcaagatga gatgcctagc ccgaccttcc 60 tcacccaggt gaaggaatct ctctccagtt actgggagtc agcaaagaca gccgcccaga 120 acctgtacga gaagacatac ctgcccgctg tagatgagaa actcagggac ttgtacagca 180 aaagcacagc agccatgagc acttacacag gcatttttac tgaccaagtt ctttctgtgc 240 tgaagggaga ggagtaacag ccagaccccc catcagtgga caaggggaga gtcccctact 300 cccctgatcc cccaggttca gactgagctc ccccttccca gtagct 346 194 230 DNA Homo sapiens 194 actgctcttt tattcaatgg aacatccccg ctttagccag tgttgaatct aacaccgaaa 60 aaagcccaga gaaatttctg cagataaacc agtgaagaga acgcgcagta tacattattg 120 tcaacagaat cacttcatgg agagggaagc gggaggaaaa aggaaggaga atgaacaagg 180 ggctcaaacc cctacacact gcaaaacatt cagacatttg ggattaaaac 230 195 611 DNA Homo sapiens 195 catatgaaat tctaataaat ccattttatt tgtggcacca caatattatc attaagctct 60 ctttttacac agtctgcaat ttgtatcagc tgccccagtg tgactctgcc cttattttag 120 gaacaacctt ttgctgggtg gcgtcctaga aggtctgggc ctgggcagca gcgactggga 180 agcccacctg tgctttcccc catctgggtg gggcggcaca gagaccctga gaatcagcgg 240 ttatgggagc tgtgtgttag ctgtgtgtta ttggctttgg cttcagcatg tcctgcctag 300 gagtctccag cagctgtggt ttccttggac tggaggcttt ttctcctgat gacaatcgtg 360 acaggtccat caggcagtgc gttgatgatg ttccaggctt caaaccgtgt gaggccctgc 420 atggcagtgc cacccagctg caagatttca tctccaggct ggactgtctc actttgttct 480 gaggctgctc ctttgaaaat cctgttaatg gtgagaagct tgtctccgtg tagggagccc 540 ttccctcctt ccaggctgta gcccagccct gccgacatct tctccatggt caccgtgaag 600 actgtggcct c 611 196 502 DNA Homo sapiens 196 gcacagggct ggctctgtgc aggctccaat ctaggacaca attatcttta atctttgttg 60 gcctaaaaat cctctagcat tgactaaccg gttcaatcct cctccagcaa gtatgtggac 120 tggacttgtg tgatttctgg tcctgacttc ctttggtttg ctcaggttca cagagtgttt 180 ccaaatgggc tggcctccca ggaagggact attcagaagg gcaatgaggt tctttccatc 240 aacggcaagt ctctcaaggg gaccacgcac catgatgcct tggcatcctc cgccaagctc 300 gagagcccag gcaagctgtg attgtcacaa ggaagctgac tccagaggcc atgccgacct 360 caactcctcc actgactctg cagcctcagc ctctgcagcc agtgatgttt ctgtagaatc 420 tacagaggcc acagtctgca cggtgacact ggagaagatg tcggcagggc tgggcttcag 480 catggaagga gggaagggct cc 502 197 412 DNA Homo sapiens 197 cgcggagaaa aaagttctcg ccaccaaagt ccttggcact gtcaaatggt tcaacgtcag 60 aaatggatat ggatttataa atcgaaatga caccaaagaa gatgtatttg tacatcagac 120 tgccatcaag aagaataacc cacggaaata tctgcgcagt gtaggagatg gagaaactgt 180 agagtttgat gtggttgaag gagagaaggg tgcagaagct gccaatgtga ctggcccgga 240 tggagttcct gtggaaggga gtcgttacgc tgcagatcgg cgccgttaca gacgtggcta 300 ctatggaagg cgccgtggcc ctccccggaa tgctggtgag attggagaga tgaaggatgg 360 agtcccagag ggagcacaac ttcagggacc ggttcatcga aatccaactt ac 412 198 534 DNA Homo sapiens 198 tttttctttt aaatcatgac acttggtagg tttaccacca gcatccaaaa tgaacaaaaa 60 cggaaaaaaa agcatttact atatatttca gatttctttg gttggggttc tccccatgtg 120 gtattaatat ttcttgtttc aatatatata ttaccaaaac agtaaaaacc aggaaaaaaa 180 atagaaacct agcggttgct gaaactagag aggctactct cttgtcttcc gtgcaggaat 240 tcccaggttc tcagcttgct ggaaaaattt gttgacattt tctttttgta gctgtttctt 300 aaagaataac agtaaacatt ccaatgtcca aatcttggtt agtcttccac tttattgctt 360 ggatgtttct ttggtgttgg ttaaggttgt ggcctgcttt ttgctttatt tctgaatggt 420 cattaattct ttaggtcacc tgccgatggt gaaggtgcct gaggagcctg gtgttactca 480 gcactgctct gctgggtggg tggagcaggg ttctcagttg gtgcttcacc tgcc 534 199 455 DNA Homo sapiens misc_feature (1)..(455) n is a, c, g, or t 199 agaggagcgg agcgggcagc gggaaggggc gcgctccgct ggccgccgag ccgcacttgt 60 ccaacgtgga aaacccaaat accagtttca aacacttggg aaacattcag ccccgctgcg 120 cagcgcgcat gcgccccggc cccctccccc ggcaacggcc ccgccccccg ccgcattcac 180 gcccctcacc gtcccaggcc ctgggggctg cgggctcgag gccggccctc gcggnggcgt 240 ggccttgcct gtcacttttt ccagaggcga gggtcgcgga ggggacagcg tcagggccgc 300 tggggtgtgg acggcgggcg aggcgcaaac tttactagga gtttttggca cttggaggca 360 gagcctgttg ggcggcacag cacgcccgct gggaaacgca ggggagcggc ctgcttcgct 420 gaaaacccga ccaggaccta acgggccgcg ggaca 455 200 478 DNA Homo sapiens misc_feature (1)..(478) n is a, c, g, or t 200 ggctgcggta gttgctgtgt accatggtct cggaggtttc tgtcccgcgg cccgttaggt 60 cctggtcggg ttttcagcga agcaggccgc tcccctgcgt ttcccagcgg gcgtgctgtg 120 ccgcccaaca ggctctgcct ccaagtgcca aaaactccta gtaaagtttg cgcctcgccc 180 gccgtccaca ccccagcggn cctgacgctg tcccctccgc gaccctcgcc tctggaaaaa 240 gtgacaggca aggccacgcc cccgcgaggg ccggcctcga gcccgcagcc cccagggcct 300 gggacggtga ggggcgtgaa tgcggcgggg ggcggggccc gtgccggggg agggggccgg 360 ggcgcatgcg cgctgcgcag cggggctgaa tgtttcccaa gtgtttgaaa ctggtatttg 420 ggttttccac gttggacaag tgcggctcgg cggccagcgg agcgcgcccc ttcccgct 478 201 619 DNA Homo sapiens misc_feature (1)..(619) n is a, c, g, or t 201 tcctcgtcct cctcgggggc ctaccgagcg gctacggcgc tcactgaccg cgtccgtacg 60 gcatgctggc gggcaacgag aagctaacca tgcagaacct caacgaccgc ctggcctcct 120 acctggacaa ggtgcgcgcc ctggagggca caacgcgagc atagaggtga agatccgcga 180 ctggtaccag aagcaggggc ctgggctcac cgcgatctac agccactact acacgaccat 240 ccaggacctg cgggacaaga ttcttggtgc caccattgag aactccagga ttgtcctgca 300 gatcgacaat gcccgtctgg ctgcagatga cttccgaacc aagtttgaga cggaacaggc 360 tctgcgcaat gagcgtggag gccgacatca acggcatgcg cagggtgctg gatgagctga 420 ccctggccag gaccgacctg gagatgcaga tcgaaggcct gaaggaagag ctggcctacc 480 tgaagaagaa ccatgaggag gaaatcagta cgctgaggag gccagtggga gagcaggtca 540 gtgtggaggt agattcgctc cggcacgatc tcgccanatc ctgagtgaca tgcacgcaat 600 atgaggtctg gccagcaga 619 202 528 DNA Homo sapiens 202 ctgaaagggt gcgccgagtc agataacctc ggacctgctc atctggagct gctccgtgtg 60 gccagcgacc tcccggttca attcttcagt ccggctggtg aaccaggctt cacatccttc 120 cggttctgct cggccatgac ctcatattgg cttcgatgtc actcaggatc ttggcgagat 180 cggtgcccgg agcggaatcc acctccacac tgacctggcc tcccacttgg cccctcagcg 240 tactgatttc ctcctcatgg ttcttcttca ggtaggccag ctcttccttc aggccttcga 300 tctgcatctc caggtcggtc ctggccaggg tcagctcatc cagcaccctg cgcaggccgt 360 tgatgtcggc tccacgctca tggcagagct gttccgtctc aaacttggtt cggaagtcat 420 ctgcagccag acgggcattg tcgatctgca ggacaatcct ggagttctca atggtggcac 480 cagaatcttg tcccgcagtc ctggatggtc gtgtagtagt ggctgtag 528 203 337 DNA Homo sapiens 203 ataatttgcc aagataaatc acttttatct ctataggaaa gggaggatct aaaaaaaata 60 taaattacat tagtaacaca acataagaaa aagacaggga caaaaacaac agagaagtct 120 gaatgatgct accctaacct atttataaaa aggccctgca tcagaaattc acaatcctac 180 ccacttctaa aaatatattt agacatgtac agaagcggtg ggcttgtttt taaattgttt 240 gctttatttg taaaaatata ttaaaggtga atagaaatcc tctctccctt ccccctgtcc 300 agcccccagc tagggactgg agatcagggg taactat 337 204 342 DNA Homo sapiens 204 cttttagctg gctacacatg aggccacttg ttttagggtg agctccaggg atttgcctgg 60 attttgaaat catgtagaac attatccacg tggctgtggc tgtggctgtg gctgggccct 120 ggcaggtgga aaaccatctc ccagaaacct gaaatcacct gccaatgacg cagataaccc 180 tggccctaca gcctgcttgc tccgcctata ccacagagca cagcctggac attatggagg 240 gtgtggcggg acggccacac ctgggtcctc catcgggaac ttttcatgct tctttctcca 300 cctgaggtct tggtctgaag aagacctcag gactcacatc tt 342 205 399 DNA Homo sapiens 205 gcaatcataa aataacttta ttggtcaggt tagccaccac tcatgctttt cctgtaataa 60 ggatccttta taaaggcatg atggtgttca catgcagatg ctttctgaag agccctgggg 120 cagggggcag ccttgcccct cacatcggag ctcctttgtt gaaatgagct ggtttggctt 180 ttgtggattc caggtctgga gccaagaacg tagtccaaag atcccctctt cccttctcag 240 ggaaggtgct tcaaagcata cacagtatca gggatgtgat ggcatctggg cagagctata 300 cttgggctaa ctctcctcca acagtccttg cccctgactg cccagatggc tttgtcccaa 360 ccttgcccaa aggacggtgg gttaagccca ggcaacatt 399 206 437 DNA Homo sapiens 206 aatgtatagg gctatatttt ggcagctggg tagctctttg aaggtggata agacttcaga 60 agaggaaagg ccagactttg cttaccatca gcatctgcaa tgggccaaac acacctcaaa 120 ttggctgagt tgagaaagca gccccagtag ttccattctt gcccagcact ttctgcattc 180 caaacagcat cctacctggg tttttatcca caaaggtagc ggccacatgg tttttaaagt 240 atgagaaaca cagtttgtcc tctcctgtta tccaagcagg aagattctat atcctgatgg 300 tagagacaga ctccaggcag ccctggactt gctagcccaa agaaggagga tgtggttaat 360 ctgtttcacc tggtttgtcc taaggccata gttaaaaagt accagctctg gctgtggtcc 420 gtgaagccca ggccagg 437 207 360 DNA Homo sapiens 207 ttagagctta atggaatttt attttgaaaa tatggcaaga gtctaaggca cttcaaacat 60 ttaaatacat agaggaccaa agtaaatgtg acacggtaaa aaggaatcca taaatacaaa 120 gagaacactg tgtttctcta gaggcaaata cagagccgat tcctctaaca caatccaacc 180 tttagcattg gagttgtgca attaatacaa atgatgatgt tacgtgtagt tcttcatggc 240 tttagtatgg aatacaaaag ctgaaaatac tgtgtcaagt tcatatagat acccttttta 300 taaaaagtca tatattacat ctacctagtt aagaccaaat gagaatattc ttttgtaagt 360 208 386 DNA Homo sapiens 208 ctgtgtccta atttattatg actacatagc ccacattcct ctgcccacgc atccgtggag 60 tccagagccc agaaagcctc ctgctgccct gccagaccgt tgagctcctc aagagcgaag 120 tgtggcacag gctgatcagc tcatgcagaa tggcagggct tcagctgccc aagtgtgtgc 180 gtaccagagc acagcattca tgaagctgtc tgactccacc tccacctctg ataatgcgtg 240 ggtgcttttg ggatagagca ggagccgaac aggcacattc cgggtcttga gggcacggta 300 atactccatg ccctgcttga agggcacacg ccggtcctcc tggcccaaca tcagtaacag 360 tggtgtcttc acctgaggga tgtatc 386 209 343 DNA Homo sapiens misc_feature (1)..(343) n is a, c, g, or t 209 ttcccagcca tgctttgcaa gatgggcttt gcggtacata ctagtgaact atcgtgaatc 60 cacgggcttt ggccaggaca gcatcctcac cctcccaggc aatgtgggac accaggatga 120 gaaggatgtc cagtttgcag tggaacaagg agcaccagga ggaacacatt gatgcaagcc 180 atgtggacct tatgggtgga tcccatggtg gcatcaatac cagccacatg attggtcagt 240 aaccagagac ctncagggcc tgagtggcac gagaacccgt gataaacata gccaccatgt 300 agggcaccac tgacatccct gactggtaag aggtggaggc tgg 343 210 388 DNA Homo sapiens 210 ttttttagtt aaatacgcac aattttattg attgaagaga ttaggacaaa aacattaaac 60 caaatacagg acaaagcacc agaggccata gatccccacc atgcatgtca ccaacctctc 120 ctcctccaag gtacttaaaa aattggggag aggggaaaaa aaaggtcctt cttgacacag 180 caccatcttc agaatgttaa aaaaaaaaaa aaccttctct cctttctatc ttccattagc 240 aaaatagaat caagggcaaa tccatggccg ccttgtctcc tggttacgaa gggtgaagcc 300 gccctcctgg gaacgtgagg acagggctcc tgctgcgcag gcataaagca tccaagagtc 360 tgcacataca tgccacacac tattatga 388 211 595 DNA Homo sapiens 211 aagagagagg caattttatt cttccaaaaa aatgcaccaa gagagggtga gcacaggagc 60 acccctggcc acatccccca tcctaagcag ggtctgagat gaggccaggc ctgacgtggg 120 cttgggagaa gctgacggag ctccctgtgg ccttggggag ggaaccaggc agacctggaa 180 gtggaacttt gttgttagca ccaggagccg cccacagctg ggctcggcaa cagggcagca 240 catggccctg ttgctgccac ctgagagtct ggggaggggc tggtggcaga aggctccctg 300 caggaggtca cctgaatgac tctcagattc acagaccccc tctgccccca caacccctgt 360 aaacatgaga atgggctcgt gacaccctca acacctcagg acaagatgag ggtccgagat 420 gtgtggctgg gcttcaggcg gcccaggagc tgccgggctt tctcctgcat gaaaagctgg 480 tccctggtcc ccccgcaggc caccgtcttc caggcactgg acataggggc aggtgtcgtg 540 aagtggcttc ggggcttctg ggccactgct gccttctcgg gcttggctgc aagaa 595 212 450 DNA Homo sapiens misc_feature (1)..(450) n is a, c, g, or t 212 attcggaaca ccggacgcaa tcaagaaagt ccggaagtct ctggctcttg acattgtgga 60 tgaggatatg aagctgatga tgtccacact gcccaagtct ctatccttgc cgacaactgc 120 cccttcaaac tcttccagcc tcaccctgtc aggtatcaaa gaagacaaca gcttgctcaa 180 ccagggcttc ttgcaggcca agcccgagaa ggcagcagtg gcccagaagc cccgaagcca 240 cttcacgaca cctgccccta tgtccagtgc ctggaagacg gtggcctgcg gggnggacca 300 ggnngaccag cttttcatgc aggagaaagc ccggcagctc ctggggccgc cctgaagccc 360 angccacaca ttctcgggac cctcatcttg gtcctggaga gtgttggagg gggtgtcacg 420 agcccatttc tcatggtttt acaggggttg 450 213 408 DNA Homo sapiens 213 gaaagaaaga gtggaggggt taacatgggg cccacctcac aacccactct tcacccccaa 60 aatcacgcag ggatgggact caggaaaggg aagcatgtgt gtgttgaata ggagccctaa 120 ctgtagttac ttctttcaca gcagggaagg aagagggaag aggcagctgt ggagaggatg 180 aggttgaggg aggtggggta tctcgctgct ctgaccttag gtagagtcct ccacagaagc 240 atcaaagtgg actggcacat atgggctccc ttcacaggcc acaatgatgt gtctctcctt 300 cgggctggtc cggtatgcac agttggggta cctggagccg tttgtcaggc ggcagtctgt 360 gatgtgcatg ctggagttgc tcttgtagca gttgccctgc ccgttctt 408 214 334 DNA Homo sapiens 214 cctggtagat gtccagaatg tctgtttcca ggaaaaggtc acctgcaaga acgggcaggg 60 caactgctac aagagcaact ccagcatgca catcacagac tgccgcctga caaacggctc 120 caggtacccc aactgtgcat accggaccag cccgaagaga gacacatcat tgtggcctgt 180 gaagggagcc catatgtgcc agtccacttt gatgcttctg tggaggactc tacctaaggt 240 cagagcagcg agatacccca cctccctcaa cctcatcctc tccacagctg cctcttccct 300 cttccttccc tgctgtgaaa gaagtaacta cagt 334 215 310 DNA Homo sapiens 215 gggttttacc agttttattt ctagactttc atgtttgtct ttttgtcttc tgctggaaac 60 atgccggtta catgttggtg ctgggaagcg ccgcgctgca accagaaatg cacagaccca 120 gccgcccgcc gcccagaccc tcagacttgc gcgtcacagg acagactccg ctgtgccccg 180 tgcacttgcc accagccttt ggcgtctcga tacacacaac atccaggact tgtgcccttg 240 ccccatcacg acagacaaag cgtccctcaa ggcccccgcg tggttcagac agacgccgca 300 gccaggatgg 310 216 493 DNA Homo sapiens 216 gccagctcac agtgctgtgt gccccggtca cctagcaagc tgccgaacca aaagaatttg 60 caccccgctg cgggcccacg tggttggggc cctgccctgg caggatcatc ctgtgctcgg 120 aggccatctc gggcacaggc ccaccccgcc ccacccctcc agaacacggc tcacgcttac 180 ctcaaccatc ctggctgcgg cgtctgtctg aaccacgcgg gggccttgag ggacgctttg 240 tctgtcgtga tggggcaagg gcacaagtcc tggatgttgt gtgtatcgag aggccaaagc 300 gtggtggcaa gtgcacgggg cacagcggag tctgtcctgt gacgcgcaag tctgagggtc 360 tgggcggcgg gcggctgggt ctgtgcattt ctggttgcac cgcggcgctt cccagcacca 420 acatgtaacc ggcatgtttc cagcagaaga caaaaagaca aacatgaaag tctagaaata 480 aaactggtaa aac 493 217 509 DNA Homo sapiens 217 tctttattga atgagggttg tcaggagcaa aggtgggatc aagagcagca aaagcagaaa 60 caagtataaa agtatcaaaa aatacaaagt gctagcactg aggagagtga gaagggttgg 120 gttgtggccc agagggacct ctgggacaca ggattgagga cttgccacag cctccaaggg 180 aacctaggcc tggggggcgt gtgcaggatc cttggctgag ggtggaagtg gcttgagcgg 240 ggcccaaccc tgggccgtga agtatgagac cagttgtgtg ggcacttctg cgagcacggt 300 ctgtgccaat gcctcccgag gggcattctg gaaccggcgg tagggtacaa actgcacaat 360 gtcgcgggca gcacctgccc agaacgtgta tgcaggggtc caccatcagc gtccagctgc 420 tccatggcct caaagtcagc accagccaca cccacattga tcactgacat gggcaggttc 480 gaggcacgca ccacagcctc acgtgtggg 509 218 52 DNA Homo sapiens 218 ggtcggtctg ttcttttgcg gttctgctct tgccctgtgt tctctttgtc tc 52 219 533 DNA Homo sapiens 219 ccagagctaa acaatttaat ataaaaaatg ccattttttg tccatacagt atttataaaa 60 aagtacatag tggttagttt tgcaataatt tctttttagc cagatgtcat atcatcatat 120 aaatctatga atataacaaa tgacataaga acagtataaa taagtttttg tagtatttac 180 acttacacag aaactagccc aaatggtgtc ctaagaaatt gtttacagtt aaagtgaaac 240 tactgattca acatactgac actccaatgc tttttaaagt ttcgtattat tttctatact 300 agttttggct atgattttgc atagaattac ttataaagta tgagcatttc acatcacagt 360 aggagctttt agtataatag tacaaaaaaa ctagctacga aaaggtcaaa tcctcctaaa 420 tctagttttt cttaaaatct ggcttctaac tttgggaaaa agaaaacatt ggcatcactt 480 gtttgctgca gggagtattc accaggagaa taaggtgtta cctcttcatc acg 533 220 343 DNA Homo sapiens 220 ttcattcaat ttcctttaat gagtacttgt tacagtaaaa gaggtataaa gtcctgttcc 60 caagtccaaa ccacttttta acttaaatct tgagtttttc tgaattactc aatttgaagt 120 aattctcttt atatctgaaa aatggtttta ttgaaacgtt tgagattaaa aaatatgcat 180 tgcaagaagc atatgacaaa cattctgaga gtacaaaatt agttgtaaaa aataacataa 240 tttaccagta aacccactca tatagaaatg tgcaaagcct tttgatataa aaagttttgt 300 acaccaagca cctattttta taacttagct tcccatggag aga 343 221 393 DNA Homo sapiens 221 atttgttaaa cagtttaatt cccaaagcta gtaattttag ttaaatatac attagagcct 60 ttttagatgg ctgctaataa acactatgtc aaaatgtgta gttttaaact cagactcgaa 120 agccaagata agcaactcct tcagttatta ctctgaccaa ggcataagaa ttcacttaga 180 caaaaagctt tcaaaaccta cctaaaaata agatagttca taaattttca aaactgttct 240 tccctgttgc ggacagccct tgatctttgt aagacttagc aaattttggc atgctctcat 300 gttagctttt taagttactg aaaactccta taaatttagc atcatttctc aaatctgtat 360 agttttctca ttccgaatgc ttaaacattt agg 393 222 565 DNA Homo sapiens 222 ccctacaaaa taatttattg gaacacacag ctacagcact ctatgtacaa gcacattgac 60 gctcctgact atcctcaact aggggaccct tttcttcccc cttgccttgc ggacctcttc 120 tatcaaatct ttcaggtact ggatctcctt ggccagggaa tccgccctct cttttagagc 180 ctcgttcttc ttttccagct ctttgcactc accagtaaga gcctcctgct ccgccctctt 240 cttctggcgg tacctagtgg ctgctgtctt gttttgctcc atttttttca gcttcttatc 300 cagtttctca ccctttactt ttgctgctac catcttctct ccaggaggat cgtaaggttt 360 gggacgggca gacccacaga gaacacctgg agatgggagg ctcctatttg gagagcccct 420 ggtagagggg ctgtgctgag gagaccccag ataggactct gggctcatac agatgccact 480 atcattatct gaaggggtgt cttcctcctt tatgcactga gggatcatgg caacgtaagc 540 agtgtagtct ggcttcctat ctcct 565 223 716 DNA Homo sapiens 223 tccaaatcaa tttattatcc tgacagctgg catcattaat actttaacaa aaccacttaa 60 aattagccaa atatctaaga cagatacata tacaaaagat atacaaatta aaaccattta 120 aaaagtaata gataccataa tttgtacttg gccacaactt ctgtattcag aaatgattgt 180 aaaattaaaa cctaagttaa aaactgtaca ccatatactt tgagtgattt acatcttaga 240 aaacaaaggc agtctttcat tgttacagat ttagtgtctc tggtgggttg aggagagaaa 300 caccatgata ctttgaattt ttgtactttt ctcttattga ctgttgtgca tgctgtggtg 360 ctttgaggta ggtctggtga aggtccatga gacaaggctt aagactttcc agggtatatc 420 cagtctttcg tattaatgat tcaggccagc tttgtcccgt gactgtgtag agtgctaaat 480 gaaaggcagc tccagcaata actgatggca aatacttgag gtatgggtca gcatctatca 540 gacttaattc tcccaaaaac attgctaaac tttcaacttt gcagtttgca ggctactgat 600 gcagaaagta ttggggaaga aactgattta ctggtgggag cagctaagtc aaaagtaagg 660 gactttcaaa aactagatgg ctccattgct caggaacttg tttacctggg tggagg 716 224 21 DNA Homo sapiens 224 gatgacgaca ggccgatgat t 21 225 21 DNA Homo sapiens 225 tgaccaggac tgcgttccat t 21 226 22 DNA Homo sapiens 226 cccgctgtag atgagaaact ca 22 227 22 DNA Homo sapiens 227 tctcccttca gcacagaaag aa 22 228 22 DNA Homo sapiens 228 atgactgagt acctgaaccg gc 22 229 22 DNA Homo sapiens 229 cagagacagc caggagaaat ca 22 230 22 DNA Homo sapiens 230 ccagctgtgg tattccaaac ca 22 231 22 DNA Homo sapiens 231 tgagcagctc agttcagttc ca 22 232 22 DNA Homo sapiens 232 gctggcctga atcattaata cg 22 233 19 DNA Homo sapiens 233 gcatgctgtg gtgctttga 19 234 22 DNA Homo sapiens 234 aggtctgcga ggaacagaag tg 22 235 19 DNA Homo sapiens 235 tgcaggcggc tctttttca 19 236 22 DNA Homo sapiens 236 tgctgcaact cctctccttc at 22 237 21 DNA Homo sapiens 237 cgtcttgctc ggattgttcc t 21 238 22 DNA Homo sapiens 238 catggtgcta ctcttgctgt ca 22 239 10 DNA Homo sapiens misc_feature (1)..(10) n is a, c, g, or t. This sequence is a place holder. 239 nnnnnnnnnn 10 240 22 DNA Homo sapiens 240 ccctgtaacg ttgaaccagt tg 22 241 22 DNA Homo sapiens 241 ggaaaagaca tcaaccccca ta 22 242 22 DNA Homo sapiens 242 tctggttgtg gtctctggtg tt 22 243 21 DNA Homo sapiens 243 gcggcactgc aggtgtaatt a 21 244 21 DNA Homo sapiens 244 ttcccttagc cagtcgatgg t 21 245 22 DNA Homo sapiens 245 ctgcctcgca atacttcatg ct 22 246 22 DNA Homo sapiens 246 ccacacccac aatgatcact ga 22 247 21 DNA Homo sapiens 247 ggcaggtgca gatgtgatca t 21 248 20 DNA Homo sapiens 248 tggctccaac agcattgatg 20 249 22 DNA Homo sapiens 249 cacacaggta ctcgtcctca ca 22 250 20 DNA Homo sapiens 250 tcgcacatgg aacacttgaa 20 251 21 DNA Homo sapiens 251 ccattcctgg tcacgcaaaa c 21 252 22 DNA Homo sapiens 252 tcctgtgtgg taggcacctg aa 22 253 22 DNA Homo sapiens 253 ccgtctgtct cctttccttc tg 22 254 22 DNA Homo sapiens 254 tcctgtcctc tgctctgtgg at 22 255 21 DNA Homo sapiens 255 tgctcccctg tttttgtgac a 21 256 22 DNA Homo sapiens 256 tcctggaagt aatgccaact ca 22 257 22 DNA Homo sapiens 257 ggcctagagc ctcttgattc aa 22 258 22 DNA Homo sapiens 258 ttgctcctct cactccatgt gt 22 259 22 DNA Homo sapiens 259 cagctggctc gatagtcgta aa 22 260 22 DNA Homo sapiens 260 tctaggagga gcccagtctt ca 22 261 22 DNA Homo sapiens 261 aaaagccatc ccagctcagt ag 22 262 21 DNA Homo sapiens 262 cacatttcca ggaacgacga t 21 263 22 DNA Homo sapiens 263 aggagctggt gtgcaaggtg tt 22 264 22 DNA Homo sapiens 264 ccccatagct tcgctcaaag aa 22 265 22 DNA Homo sapiens 265 gcagccggag aacaactaca ag 22 266 20 DNA Homo sapiens 266 tgcatcacgg agcatgagaa 20 267 21 DNA Homo sapiens 267 tcccatggca agtcctaaag c 21 268 22 DNA Homo sapiens 268 ccatgacaca gccaaacaga aa 22 269 22 DNA Homo sapiens 269 tctcatcgtg tcacaactgc aa 22 270 22 DNA Homo sapiens 270 gagctgcttc tacgtccaac tg 22 271 22 DNA Homo sapiens 271 cagcgtttcc tgcattgtca tc 22 272 22 DNA Homo sapiens 272 gacccctgag catcctggat ta 22 273 21 DNA Homo sapiens 273 ggagctcctc atgaacgtga a 21 274 19 DNA Homo sapiens 274 aggtgtcttt cccgttgca 19 275 21 DNA Homo sapiens 275 ctaacgcagc agttgcaaac a 21 276 20 DNA Homo sapiens 276 tctccgtcgc aacttgtcaa 20 277 22 DNA Homo sapiens 277 atggctcctg ctgtacctca ag 22 278 22 DNA Homo sapiens 278 gtgaagcggt ggacaagaaa ct 22 279 20 DNA Homo sapiens 279 cgaagctgtt gttcggaatc 20 280 22 DNA Homo sapiens 280 ggctggtgta gcagatcata cc 22 281 22 DNA Homo sapiens 281 aacctgccag atgcttgtga at 22 282 21 DNA Homo sapiens 282 cggtgtcatc aattgctttg g 21 283 22 DNA Homo sapiens 283 gctccattac caagagctca tg 22 284 21 DNA Homo sapiens 284 gtgcctggtc agttcatctg a 21 285 20 DNA Homo sapiens 285 gcatgaaagc tgccttggaa 20 286 22 DNA Homo sapiens 286 cctgattctg ccgctcacta tc 22 287 22 DNA Homo sapiens 287 cagaagccga gtcctggtat ca 22 288 20 DNA Homo sapiens 288 tggcgcactg tttcttgaca 20 289 22 DNA Homo sapiens 289 agcagaaaga gtggcagagg at 22 290 22 DNA Homo sapiens 290 ttggtggaag agctgttgat gt 22 291 22 DNA Homo sapiens 291 ggtggatctg tcagctgcca ta 22 292 22 DNA Homo sapiens 292 gcctgtcacc tcagaactcc aa 22 293 22 DNA Homo sapiens 293 cccatcaaga aagtccggaa gt 22 294 21 DNA Homo sapiens 294 gcagttgtcg gcaaggatag a 21 295 22 DNA Homo sapiens 295 tccactgcat cattcagctt tc 22 296 21 DNA Homo sapiens 296 tctccaaagc gaggtcttcc t 21 297 22 DNA Homo sapiens 297 agctcagaga cccgcagcat ta 22 298 22 DNA Homo sapiens 298 actgaggatc accaggcctt tg 22 299 22 DNA Homo sapiens 299 gcccatcatc atttccattg tg 22 300 22 DNA Homo sapiens 300 tgaacacctg catccttgaa ga 22 301 19 DNA Homo sapiens 301 tcgcaaaggt cccatttcc 19 302 22 DNA Homo sapiens 302 cgtagagctg aggagcgaca at 22 

We claim:
 1. A method of differentiating between benign reactive lymph node tissue, follicular lymphoma tissue, mantle cell lymphoma tissue and small lymphocytic lymphoma tissue, comprising: hybridizing labeled RNA from tissue with oligonucleotide probes that are differentially expressed by benign reactive lymph node tissue, follicular lymphoma tissue, mantle cell lymphoma tissue and small lymphocytic lymphoma tissue; analyzing the expression of the probes.
 2. An array comprising at least two isolated nucleotide molecules, each molecule having a sequence capable of uniquely hybridizing to a nucleic acid molecule having a sequence with at least 70% homology to a sequence listed in Table
 2. 3. An array comprising 120 nucleic acid molecules or spots, each spot comprising a plurality of isolated nucleic acid molecules, each molecule having a sequence consisting essentially of a sequence of Table
 2. 4. A method for determining the expression profile of a sample containing nucleic acid comprising: (a) providing the sample; (b) providing an array of claim 3; (c) contacting said array with said sample under conditions allowing selective hybridization; and (d) measuring hybridization of nucleic acid in said sample to said array to produce an expression profile. 